- the International Energy Agency`s Energy in Buildings

Transcription

- the International Energy Agency`s Energy in Buildings
IEA-SHC Task 28/ECBCS Annex 38
Sustainable Solar Housing
Exemplary
Sustainable Solar Houses
A Set of 40 Brochures
IEA-SHC Task 28/ECBCS Annex 38
Sustainable Solar Housing
Exemplary Sustainable Solar Houses - a Set of 40 Brochures:CONTENTS
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Brochure
Passivhouse in Gaspoltshofen, Austria
Plus Energy House in Thening, Austria
Demonstration Projects Passive Housing Utendorfgasse 7, Vienna, Austria
Demonstration Houses in Cernosice, the Czech Republic
House W – Demonstration House in the Czech Republic
Demonstration Houses in Tuusniemi, Finland
Ultra Low Energy House, Durbach, Germany
ISIS Demonstration Housing Project in Freiburg, Germany
Demonstration Houses in Hannover-Kronsberg, Germany
Kassel, Germany
3-Litre Townhouse, Celle, Germany
3-Litre Twin Houses, Ulm, Germany
3-Litre Urban Villa, Celle, Germany
Chignolo, Italy
Chiryu, Japan
A Zero Energy House (a low energy house with PV system) in Kanagawa, Japan
KankyoKobo: Sunny Eco-House
A low energy house with 1) all heat exchange type central air conditioning
ventilation systems, 2) passive solar, 3) the photovoltaic system, Kyoto, Japan
Okayama, Japan
A Sustainable Solar House with OM Solar System in Hamamatsu, Japan
(in Japanese)
Example of a Prefabricated House with Solar Power Generation System, Japan
Waaldijk, Dalem, The Netherlands
Groenlo, The Netherlands
Rivierdijk, Sliedrecht, The Netherlands
Kakariki Lane, Christchurch, New Zealand
Budstikka 18, Kongsberg, Norway
Husby Amfi, Stjordal, Norway
Landskrona, Sweden
Goteborg, Sweden
Buttisholz, Switzerland
Dintikon, Switzerland
Konstanz, Rothenburg, Switzerland
Monte Carasso, Switzerland
Sunny Woods, Zurich, Switzerland
The Zero-Heating House, Peterculter, Aberdeen, Scotland
Hockerton Housing Project, UK
Foley House, Rothesay, Isle of Bute, Scotland
INTEGER Project, Maidenhead, UK
The INTEGER Millenium House, Watford, UK
Demonstration Houses in Kansas City, MO, USA
Passivhouse in
Gaspoltshofen,
Austria
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
Photos and graphs
The project
Marketing strategy
This single family house has been constructing as a
privat built-house and will be finished in 2004.
none
Objectives - Goals
The main goal was to construct a low energy house in
respect to economic and ecologic issues.
In addition a further supposition of the owners was an
attractive and appealing outfit.
Building construction
Most parts constructed as prefabricated segments
moveable by crane only
Of course sustainability and the use of material of the
region was granted.
(e.g.: lambswool for insulation and timbers of spruce
and larch came close to the location)
Construction type and material use, U-values, innovative elements.
Construction
Material
U-value
Wall
Timber, lambswool,
cellulose
0,11
Ceiling
Timber, cellulose
0,09
Windows
Timber, cork, 3-layer-glass
0,78
Adr. 53 / 5
t
ZULUFT
Heizregister in
Lüftungsverteiler
Adr. 32 / 0
Wohnzimmer
Wandheizung
M
Kabelfühler Ni 1000
BAD OG
t
t
Handtuchwärmer
Solar/Heizungsanlage
Fam. Leiner, Bogenstraße 11
4673 Gaspoltshofen
gez.: 22.09.2002 Lei
Adr. 48 / 0
Z1
Raumtemp-Fühler
t
Adr. 38 / 6
22
m
²
P4
M
Photos and graphs
Ausdehnungsgefäß
im Dachboden 35 Liter
Anzeige
t
Z2
M
Entlüftung
Z3
Puffer 2000 Liter
Anzeige
t
P3
I
H
Adr. 33 / 1
t
Anlegefühler
G
F
E
KFE
Trinkwasser
Kabelfühler Ni 1000
t
Puffer - Oben
t
Adr. 49 / 1
Adr. 36 / 4
Kabelfühler Ni 1000
Adr. 35 / 3
Ti Pi
255
Kabelfühler Ni 1000
Raumtemp-Fühler
FU
180
KFE
t
Adr. 39 / 7
t
Adr. 37 / 5
215
P1
Anzeige
t
195
Tacco Setter
t
Raumtemp-Fühler
M
Jagdstube
Ko
lle
kt
or
flä
ch
e
Warmwasser
Festbrennstoffkessel
165
Impulsgeber
D2
51
35
Wärmemengenzähler
Pressostat
KW
D1
t
Puffer unten
Kabelfühler Ni 1000
Adr. 34 / 2
P
P2
Pressostat
P
Ausdehnungsgefäß
neben Kessel 200 Liter
Kaltwasser
Adr. 54 / 6
Technical systems
2 stfg
Q
t
t
4 stfg
AUL
4 stfg
WRG
Kanalfühler 135 mm
Kanalfühler
62 mm
• PV – supply 2,8 kW
• Thermal collector 22 m²
• storage tank 2000 liter
• bio mass – boiler
• ventilation system
• rain water storage equipment
• EIB control
Luftqualitätsfühler
Adr. 52 / 4
Abluftbox
Adr. 55 / 7
Kanalfühler 135 mm
M
Siehe
Seite 1
Energy performance (demand per year and m²)
Reference
building
(standard
house 2004)
House Leiner
Monitored (m)
Calculated (c)
Heating of space
and Ventilation
air
80 kWh/m²a
14 kWh/m²a
(m + c)
Domestic hot
water
25 kWh/m²a
( 4 persons)
2,5 kWh/m²a
(c)
0,5 kWh/m²a (m
+c)
Lighting
7 kWh/m²a
3 kWh/m²a (c)
Electrical
appliances
12 kWh/m²a
5 kWh/a (c)
Ventilation pipes
Kanalfühler 135 mm
FOL
Nachheizung
WW - 1500 W
Zuluftbox
t
Sommerbypass auf/zu
Solar pump
ABL
ZUL
t
Adr. 53 / 5
Planning tools for LCA, energy performance, solar energy design and more
The over all performance (electricity, heating, domestic watersupply,..) was calculated by the PHPP of Dr. Feist
(Darmstadt).
Costs and benefits
Building, incl.
Wintergarden,
PV, all technical
equipment (e.g.
PV, Solarthermal
appl., rainwater
facility,..) ,
cellar
Standard
house
(in k€)
House
Leiner
(in k€)
benefits
350
400
Extraordinary space klimate due to
Plaster made of loam, loambricks,
lambswool, timber, .....
Energy savings in fact due to
wintergarden and heating/cooling
system by air
Innovative products
Windows and doors
Cork-insulated frames and 3-layer-Glasses
Ventilation and cooling
Heat recovering by interchanging and cooling
with bypass and 40 m pipe digged in earth
Controls
All systems are controlled electronically by
one system (programmable control panel)
Domestic appliances
Low energy lamps and refrigerator, washingmachine with warmwater supply by
solarthermal equipment
Space heating and domestic hot
water
Solar thermal collector 22 m² and bio-massoven. Distribution of heat by air.
Electricity
Roof-integrated Solar PV: 2,8 kW
Other information
PROJECT OWNER
Ing. Maximilian and Erni Leiner
Financer and contact person
[email protected]
Architect
Dr. Wiesmayr
Tecnical issues and coordination
Ing. Maximilian Leiner
Awards
Winner 2002 solar award
www.eurosolar.at/solarpreis_2002.html
www.iea-shc.org
www.ecbcs.org
Plus Energy House in
Thening, Austria
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
Section of “Plus Energy House”
Ground plan of ground floor
and first floor
The project
It took only 6 months to build this cozy home for one family back in 2001. It is of the ecological Passive-house type
and is made of pre-fabricated wooden components.
The building structure is compact and opens to the south. The northern part of the facade shows only the window
for the toilet.
The open, horizontally fixed timbering made of larch wood, hides a perfect thermal insulation assembly.
DWD board, cellulose insulation and OSB board complete this wooden construction.
Building construction
Basement:
Floor surface: floor tiles 10mm
Screed: 60 mm
PAE Sheet
45/42 TSDP
Polystyrene: 100mm
Impermeable Concrete: 100mm
Gravel layer: 300 mm
Composition of ceiling:
Board made from wooden material: 22 mm
Ceiling beams made of bonded plywood: 320 mm
Inter-layer of Stone wool as thermal insulator 100 mm
PAE Vapor-barrier sheet
open form work: 24mm
Fiber reinforced Gypsum core board: 15 mm
Windows
Wood frame windows for passive house with 3-pane-glazing
(manufactured by Sigg)
Wall construction
GKPL (Fermacell): 15 mm
Intermediate Installation level with 6 cm Flax insulation
Vapor barrier (Eco vapor barrier)OSB Board: 15 mm
TJI Carrier: 300 mm with intermediate Isocell thermal
insulation (Cellulose)DWD
BoardVentilation gap: 50mm
Composition of roof:
Rubber sheet
RHEIN ZINK® Sheetmetal
Lining sheet for dew drainage (open to diffusion)
Open form workVentilation
gap/rough from work: 24mm
Moisture Insulation of lowerInsulation element with
110 mm wooden board with surface dressing
Wooden board 16 mm
Ceiling beams: Ply-wood board ,
with intermediate insulation 400 mm
PAE sheet as Vapor barrier
Open form work: 24 mm
Fiber reinforced Gypsum core board: 15 mm
The living area is
equipped with energy
saving lamps (CFL)
Total load for lighting: 460W
Technical systems
Modern technical services incorporate tested
technologies, resulting in a well functioning Plus
Energy house
The two-storey structure is fitted with a 17m²
façade collector in the ground floor for the
generation of warm water.
Mechanical ventilation with heat exchanger
(efficiency: 85%) supplies perfectly filtered air and
cools or heats, depending on the circumstances
Ecological house of wooden construction, built as
passive house
Use of rain water for irrigation, toilets and laundry.
10,350 Wp photovoltaic modules which replace the
roof are connected to the grid and produce electric
energy.
Energy performance
The house is heated by a controlled air
supply for living areas with 85% thermal
efficiency. An earth heat exchanger sucks
air of currently 12 degrees centi-grade
from the soil. The air is cleaned by 2 filters.
It is then blown into the living rooms at a
velocity of 0,3 m/sec. Warm air from the
kitchen, the bath, and the toilet is sucked
away, on the way out passing the heat
exchanger.
Inlet for living rooms,
exhaust outlet and
technical services
Due to this technology and the design of the
house, there is no need for a separate
chimney.
The roof is not inclined towards the north as
is usually the case, but its highest point is
due north, and it has an angle of 10° to the
south and thus, the photovoltaic module can
be incorporated in the roof surface.
The solar modules from “Solar Fabrik” have
a surface of 86m² and come from a CO2-free
production. Consumption of the house is only
1/3 of full capacity, with the surplus being
sold to the power utilities and fed into the
mains.
An electrically driven heat pump heats the
preheated incoming air up. Because the entire air
of the house is exchanged, there is no need to
ventilate the rooms by opening the windows.
During summer, the ventilation can be used as air
conditioning using the low ground temperatures
Total energy demand: 12,8 kWh/m²
Heating of space and ventilation air: 750 kWh/a
(energy source)
Domestic hot water: 350 kWh/a
(energy source)
Fans and pumps: 320 kWh/a
Lighting and appliances: 220 kWh/a
Team:
Owner:
Architect:
Calculations:
Energy Concept:
Renewable Energy:
Kontakt:
Transmission values of components
Windows and glazed doors
0,79 W (m²K)
Exterior doors
1,20 W (m²K)
Exterior walls
0,11 W (m²K)
Ceiling of basement
0,11 W (m²K)
Roof
0,11 W (m²K)
Energy demand for heating: 15 kWh/m²a
Karin und Uwe Kroiss
Karlsreiter Andreas, Thening
Planungsteam E-PLUS
uwe kroiss energiesysteme
uwe kroiss energiesysteme
www.energiesysteme.at
www.plusenergiehaus.at
www.iea-shc.org
www.ecbcs.org
ANSICHT NORD M 1 : 500
UTENDORFGASSE
EIN- AUSFAHRT
TIEFGARAGE
HAUS 2
HAUS 1
PRIVATE G˜RTEN
PRIVATE G˜RTEN
M LLPLATZ
KINDERSPIELPLATZ
N
HAUS 3
PRIVATE G˜RTEN
E
GASS
HEIM
LIND
Demonstration-project
Passive housing Utendorfgasse 7
GRUNDRISS ERDGESCHOSS M 1 : 500
Vienna14, Austria
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
gipskartonplatte
dampfsperre
schwingbügel
staffel+dämmung
osb-platte
eps-f
dünnputz
1,2
3
5/8
1,8
30
0,5
AUSSEN
Structural system
The project
The demonstration-project “passive housing”
Utendorfgasse 7, A-1140 Vienna” was implemented
in a research project founded by the Austrian
Government (BMVIT). The goal of the research
project is the development of a building concept for
the employment of passive technology in social
housing. The houses are financed by an semiofficial housing company. The building project
should be finished in 2005/2006. The apartments
will be rented.
Architecture and structure
The three building parts cover an underground
parking space and 5 floors with 39 flats with an
average size of 73 m².
Building construction
The construction concept plans of a building of
concrete disks (basic transverse walls). This
provides a large use flexibility and is given with high
economy. Attention was given to the possibility for a
non-load bearing facade system. The thermal
decoupling between "cold" underground parking
space and the "warm" living area above the garage
takes place via a unique twist of the concrete wall.
INNEN
Cross section
Objectives - Goals
1. Passive house standard
heating energy demand
air tightness n50
heating load
primary energy demand
≤ 15 kWh/mà
≤ 0,6/h
≤ 10 W/m2
≤ 120 kWh/(m²a)
2. Planning objectives
“Specifications for social housing”
defined comfort criteria
e.g. noise level < 25 dB
Minimum sensitiveness to users behaviour
e.g. sensitiveness to unused (cold) flats
Extra costs ≤ 75 Euro/m² effective living area
Construction costs ≤ 1,055, -Euro/m²
Costs
Many investigations were undertaken to specify
extra costs and ways for reducing the costs for
passive housing elements e.g. for windows,
ventilation systems, facade, etc.
Air ventilation zo n es
Th ermal zo nes
Technical systems
Building equipment and appliances The concept of a “semi­central” ventilation system is used. The central appliance of the ventilation system consists of a central heat exchanger, air filters, supporting fans and an electric heater battery for frost protection.
The decentralized components (in each flat) are a heating battery and two speed controlled fans. The transport of the fresh air into the sleeping­, living­ and children room s is via long range ducts. From these zones the air is transferred to overflow zones (e.g. corridors) via overflow openings (e.g. openings in door leafs; joints between the walls and the door casings).
The fume extraction hoods are operated with circulating air. Water heating
For the central heat production a condensing boiler with a hot water tank is used. The boiler is fired with gas and produces the heat for both, the heating water and the hot water.
The distribution of the hot water is made with circulation pipes and a circulation pump, which is controlled with a time switch. The heat for the decentralized heating batteries is supplied by the heating water. Building physics / building services / simulation The variant of an external insulation of 30 cm gives the sm allest heating energy demand. The staircase is included in the thermal envelope. In the basic variant a heating load ≤ 9,1 W/m² and an average heating demand of ≤ 14,5 kWh/m²a at a room tem perature of 22 °C can be achieved. Between the flats U­values of less than 0,9 W/m²K according to Viennese building code should be reached. It has been shown that the influence of unoccupied flats can be called insignificant.
Without attenuators the remaining noise in the living room is higher than 25 dB
(A), which is higher than the goal for the maximum noise level. If attenuators are used long range jet nozzles can be used for the supply of air in the living room. The noise level in the investigated flat was calculated to 18 dB(A) with the use of attenuators and long range jet nozzles, which is under the limit of 25 dB
(A).
Used Planning tools PHPP ­ Passive House Planning Package 2 .0 0 0
1 .8 0 0
1 .6 0 0
1 .4 0 0
1 .2 0 0
1 .0 0 0
800
600
400
200
0
Cost Comparison of CEPHEUS passive house projects with the actual project (Euro per m²)
Project team
Financer:
Project management and Cost control:
Electrical & ventilation Services :
Building Physics:
Architect:
Statics:
Scientifically accompanied by:
Heimat Österreich, Vienna
Schoeberl & Poell, Vienna
TB Steininger, Vienna
ebök engineer‘s office, Tübingen
Kuzmich Franz, Vienna
Werkraum ZT OEG
Technical University Vienna, BBB
The research work will be published in German language. It will contain a planning guideline for all
involved planning disciplines. You find the complete text under the link www.schoeberlpoell.at .
The Project is supported by
www.schoeberlpoell.at
www.hausderzukunft.at
Demonstration houses in
Černošice,
the Czech Republic
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
Basic information
Traditionally shaped, private built, single family house
was built in 2003.
A building site for this private built house was set by
regulating plans, which do not respect optimal solar
orientation (in general: when assigning orientation of
building, roof type and other parameters, spatial
planning does not consider factors of sustainable
housing, mainly optimal solar orientation). Therefore,
gables had to be south-north oriented and solar
collectors had to be placed on the porch.
The house consists of two functional parts. First one
is living heated area of 86 sqm designed for 4
persons. Second one is an auxiliary space of 52 sqm.
The house was finished in December, 2003 and is
indwelled since.
1st floor plan
Objectives
An investor desired for a house with a minimal
impact on the environment. Hence, except
energy performance, also another environmental
aspects were considered. For example,
composting toilet and rain water storage were
set. Investor wished for biomass fire place too,
so it was compromised as a small fire-stove.
There was an challenge to build a „common“
brick house of a maximal reduction in energy
consumption and not to significantly exceed
standard costs.
Building construction
Construction of solid brick (unburnt lime-sand
bricks). Insulation 300 mm of mineral wool.
Innovative: minimal dimension of a framework
was „compensated“ by maximum of thermal
insulation. Special wooden frame was developed
for free laid mineral wool.
U-values
External wall
Socle
Roof
Floor
Windows (glazing)
U = 0,122 Wm-2K-1
U = 0,159 Wm-2K-1
U = 0,108 Wm-2K-1
U = 0,272 Wm-2K-1
U = 1,100 Wm-2K-1
Technical systems
• warm air heating, mechanical ventilation with heat
recovery
• earth heat exchanger
• solar collectors 5,0 m2
• integrated heat storage (IZT) 950 litres
• fire stove 9/5 kW
• central regulation
• lighting tube for staircase
• composting WC
Energy performance
Total energy demand: 29 kWh/m²
Space heating and ventilation air: 12 kWh/m²
Energy sources: solar energy, biomass, electricity
(low tariff)
Domestic hot water: 34 kWh/m²
energy sources: biomass, electricity (17 kWh/m²)
solar collectors (17 kWh/m²)
Parameters declared above are calculated. The
house is being monitored since January, 2004.
System was proved by failure of its active heating
part. For about 14 days there was average
temperature of 19°C by exterior temperature of –
20°C.
Note: If „super“ windows (and doors) had been used,
the passive house standard would has been
performed.
Costs
Realization costs were about 4 mio. CZK
(ca.123000 EUR). There are approximately 0,5
mio.CZK extra costs when comparing with a
common house of this standard.
Planning tools
Energy performance of the house comes partly from
former experiences of several engineers and
architects and partly from a model developed in cooperation with Czech Technical University, Faculty
of Civil Engineering.
Marketing strategy
The marketing strategy can not still be based on
economical arguments only. Economical pay-back
time is playing important role for many investors
when making decision on energy parameters, but
never plays role when making decision on baywindows, doorknobs or garages.
Marketing can be based on both environmental and
economical parameters. A standard shape and
material of such type of house can be an advantage
for rather conservative investors.
INTEGRATED HEAT STORAGE SUPPORTING THE WHOLE HEATING SYSTEM
The design principles of the house are published at venues of ECOHOUSE (association for sustainable housing) and
discussed at the website. The parameters of energy performance will be monitored in co-operation with investor.
Investor:
Detail planning and energy concept:
Realization:
Vančák family
Aleš Brotánek, Jan Brotánek
ALTERSTAV s.r.o., Vysoké Mýto
LOCALITY
(southsouth-west of Prague)
Prague)
PRAHA
www.iea-shc.org
www.ecbcs.org
House W - demonstration house in
the
Czech Republic
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
Cross section
External wall
horizontal section
vertical section
mineral wool
wood and wooden based materials:
framing,OSB, cladding
Basic information
House W is a private built single family woodenbased house, with two floors, without cellar.
Location: 15 km south of Prague, near Velké
Popovice
Built-in volume
Floor area:
Living area:
691,0 m3
190,4 m2
129,5 m2
Construction time: June to November 2003
1st floor plan
Objectives
Using a minimum amount of materials and total
primary energy from non-renewable sources was
the leading idea of the project. The house should
reach the low-energy house level with usually
accepted costs for standard housing. Both of
these facts have led to a wooden-based
construction with simple form, energy effective
building envelope and use of several
components typical for passive houses. The Uvalues of the building envelope are close to those
recommended by ČSN 730540-2 (2002) Thermal
Protection of Buildings, Part 2: Requirements.
Building construction
Wooden frame construction was completed with
OSB-boards from the exterior site of the framing,
thermal insulation from mineral wool and wooden
cladding. Polyethylene foil was used as watervapour barrier. The air-permeability was
measured during the constructing period to
prevent air leakages.
U-values:
External wall
Roof
Ceiling (loft)
Floor
Windows
U = 0,19 Wm-2K-1
U = 0,17 Wm-2K-1
U = 0,14 Wm-2K-1
U = 0,25 Wm-2K-1
U = 1,39-1,68 Wm-2K-1
(glazing 1,1 Wm-2K-1)
Technical systems
• warm air heating, mechanical ventilation with heat
recovery
• earth heat exchanger, 21 m in length, 2 m deep
• roof integrated solar collectors 8,4 m2
• integrated heat storage (IZT) 950 litres water, heated
by solar system and electricity, secures hot water at
time of use (no separate hot water storage needed)
• wood stove 7 kW (max.), intermittent operation
Costs
The investment costs were very close to the costs
for standard housing in the region. Additional costs
are caused due to larger amount of thermal
insulation (35 thousand CZK), for the solar heating
system (175 thousand CZK), for the warm air
heating system including integrated heat storage, all
ducts and installations (250 thousand CZK). The
saved costs are for conventional heating: gas ducts,
gas boiler, chimney (together 323 thousand CZK).
Finally: the extra costs compared to the virtual
reference house in this particular case are only 137
thousand CZK (approximately 4% of total
investment costs). The simple pay-back time is
about 13 years.
Energy performance
Specific (calculated) heat use for heating is
44,4 kWh/(m2 year) - approximately 1/3 of required
value. This value does not include gains from earth
heat exchanger.
Boundary conditions for calculation: efficiency of heat
recovery 75%, air exchange 150 m3 per hour when
taking into account full occupancy by 5 people.
Planning tools
Energy use was calculated according to ČSN EN
832. More detailed computer simulations will be
performed later to analyze the measured data,
especially to study the real contribution of the solar
heating system.
Energy balance
The energy balance (heating+hot water) of a
reference building with identical geometry that fulfils
the energy requirement (1) and the realised house W
(2,3) is shown below. A corresponds to heat use for
heating, B heat use for hot water, C represents
system losses. Red arrows show non-renewable
energy use.
Marketing strategy
The marketing strategy for this type of house might
follow the strategy for marketing wooden houses in
general.
There is a large potential for the wood house sector
in the Czech Republic as a significant capacity for
quality timber does exist there. Market penetration
depends mainly on to what extent „a wooden
concept“ can penetrate regional tradition and
mentality.
Monitoring
The repeated measurement of air permeability
together with infrared thermography was performed.
Monitoring of energy parameters in the first two years
of operation is in progress. A computer-operated
measurement unit was installed in the technical room
of the house.
Dům
W - Přehled
energetické
bilance
House
W: energy
balance
30
25
MWh/a
20
C
B
15
10
A
GAS
SOLAR
C
B
WOOD
A
5
ELECTR
.
0
1
2
3
Legend to the scheme:
B integrated heat storage
a earth heat exchanger
C warm air heating with heat recovery
b small wood stove (independent)
D solar collectors (roof integrated)
E expansion vessel
Scheme of energy supply
a
b
1 fresh air
2 interior air
3 outlet air
4 warmed-up fresh air
5 drinking water
6 hot water
The design principles of the house were published several times (using web and journals), presented and discussed
at expert seminars and conferences in 2003-2004.
Investor:
Preliminary design study and energy concept:
Detail planning and realization:
Thermal insulation:
Heating/Ventilation:
Solar system:
Monitoring:
Information:
www.iea-shc.org
Weger Family
Jan Tywoniak, Martin Šenberger
PENATUS s.r.o., Zlatníky
ROCKWOOL, a.s., Praha
ATREA, s.r.o., Jablonec n.N.
REFLEX CZ s.r.o. and ATON s.r.o., Praha
Czech Technical University in Prague, Group for
Sustainable Housing (Jan Tywoniak et al.),
cooperation AHLBORN CZ. s.r.o., Praha
www.tzb-info.cz
www.ecbcs.org
Demonstration houses in
Tuusniemi, Finland
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
Solar energy transmittance: 52%
Wind barrier
Daylight transmittance: 68%
U = 0,1 W/m 2 K
Roof ventilation
Bearing timber
Total U-value: 1,0 W/m2K:
- Argon filled sealed unit
Low-emissive glass
Spacer 16 mm
Float glass
- Air space
- Float glass
Technical installations
EPDM sealant
U = 0,15
Thermal break
W/m2K
EPDM sealant
and putty joint
Wide wooden frame (175 mm)
U = 0,15 W/m2 K
ppp
ppp
ppp
ppp
ppp
ppp
Expanded clay
The project
Tuusniemi is a small municipality of 3000
inhabitants in East Finland. Tuusniemi is located in
less than one hour travel time from two major
regional growth centres and university towns Kuopio
and Joensuu.
The housing area is located between two lakes,
both with extremely pure water, and bounded by
traditional rural cultivated area. Peaceful, pure, and
safe environment together with eco-efficient housing
were chosen as targets for the new housing area.
The project demonstrates how eco-efficiency can be
utilized as drivers in community economics, new
business activities, and employment in
municipalities outside growth centres.
The housing area consists of altogether 16
buildings, 13 single- family houses, two linked
houses, and a building for common use. The master
plan allows for construction of single-family houses
up to 250 m2. Two types of model houses have
been developed. These houses can be extended
from 75 - 125 m2 up to 195 - 225 m2 according to
future needs of the users. The houses are built and
sold ready-made or with existing building permission
for extension. The linked houses are together 1500
m2 with 14 apartments
The area has a distributed heating energy supply
network based on ground heat and solar energy.
The houses are built by a new company that will
take over the maintenance and management of the
area and its networks. The construction of the area
starts on March 1, 2004.
Wind barrier
Expanded clay
Objectives - Goals
The Tuusniemi municipality suffers from
depopulation and distortion of age structure. Due
to poor working possibilities, young people move
to other locations. This causes growing socioeconomic problems.
The community decided to persuade new
inhabitants to the community by offering highclass but acceptable cost housing possibilities
especially for young families. The housing area is
equipped with working facilities for common use
to enable remote working. All the houses have
high-standard internet connections. Public
services, schools, nursery, health care center etc
are available within walking distance. Public
transport connections serve for working in the
cities.
Building construction
Building envelope is based on a new open woodframed building system Nordic Platform allowing
for shorter delivery cycle than with typical
construction. Special features of the system are
250 mm wood- frame with thermal break for
exterior walls and trussed construction for
internal floors. The walls have an air tight
additional exterior insulation layer facing air
cavity and wooden façade.
Insulation thicknesses and corresponding Uvalues including thermal bridging in construction
are 275 mm (U=0,15 W/m2K) for walls, 450 mm
(U=0,15 W/m2K)for floor with crawl space
foundation, and 500 mm (U=0,10 W/m2 K) for
roof. Windows are triple glazed with one argon
gas filled sealed unit and one selective coating.
Total U-value including frame is 1,1 W/m2 K.
Technical systems
All the houses have a mechanical ventilation system
with heat recovery. Two heating systems are
introduced: floor heating and ventilation heating
system.
All the buildings are connected to local distributed
heat supply network based on ground source heat
pumps. The municipality built distributed heat pump
system consists of four separate networks according
to plot ration of building sites. Heat pumps are
operated by the maintenance company, and they
use wind energy. The yearly COP of the heat pumps
is estimated 3,0.
All the houses and apartments have a fire place
designed for a low-energy building. The design
allows for a long heat supply with low supply power.
Energy performance
The houses are designed so that the larger is the
house the less energy by m2 it consumes. The
heating energy demand can vary between 70 - 50
kWh/m2, which includes energy produced for
heating and hot water by heat pumps, and fire wood
used in the fire places. Company built houses are
required to have lower consumption than houses
built by home builders. The peak auxiliary heating
energy power is restricted to 35 W/m2.
Consumption, kWh/m²
Existing buildings
Tuusniemi
Heating energy
140 - 170
25 - 30
HVAC electricity
20 - 30
10 - 20
Household
30 - 40
25 - 35
190 - 240
60 - 85
Total
Costs
The construction costs of the houses correspond to
average costs of detached houses. The selling price
of the houses start from 100 000 € including the
site.
Planning tools
The project started with an intensive briefing using
VTT's building properties classification tool
EcoProP. The briefing tool produces automatically a
document that is the basis for code of practice for
construction. Energy analysis with regard to fire
places in individual buildings were carried out using
simulation tool VTTHouse. Life-cycle costs and lifecycle economy of the area are estimated using
VTT's life cycle economy model based on ISO
15686. LCA tool BeCost was used in environmental
assessment of the buildings.
Marketing strategy
The marketing of the housing area is based on high
environmental values introduced with safe and pure
natural environment. The main target group for
marketing is young families. A special direct
marketing effort for young families in Kuopio and
Joensuu is designed by the Design Institute of
Savonia Polytechnics. A study on the housing
preferences of target group in the regional town is
being carried out to serve as marketing aid for the
project. Information of the project can be found from
the project web-site.
The project progress is followed and publicity gained
by a project leaflet is published every two to four
weeks. The project is presented in all the major fairs
for home builders and annual housing fair in Finland.
The houses are sold by a large housing agency in
Finland operating country-wide.
Other information
Project management: Tuusniemi municipality, municipal director N.N., e-mail:
http://www.tuusniemi.fi/
Project co-ordinator: Architect Kimmo Lylykangas, e- mail: [email protected]
http://www.arklylykangas.com/
Project web-site: http://www.hietaranta.net/
Research: VTT, Jyri Nieminen, e- mail: [email protected]
http://www.vtt.fi/
Nieminen, J. Eco-efficient housing as driver in community economics. Paper to ENHR European
Network on Housing Research Biennial International Housing Conference. Cambridge, UK, 2-6 July
2004
Common text about Task 28
www.iea-shc.org
www.ecbcs.org
Ultra low Energy House
Durbach, Germany
IEA-SHC Task 28 / ECBCS Annex 38:
Sustainable Solar Housing
First Floor
Ground Floor
Building characteristics
Building volume Ve
576 m³
A/V
0.67 m-1
Useable floor area AN
184 m²
In 1996, a timber-construction double house was built in
Durbach near Freiburg within the framework of the
"Weber 2001" project. One half of this building was
conceived as a low-energy building, the other one as an
ultra-low-energy building. This paper presents the ultralow-energy building, which is also offered by the
manufacturer as a single-family house (see photo). The
two-storied building has a usable floor area AN of 184 m²;
the building has an air leakage characteristic A/V of
0.67 m-1. The living room, the kitchen, a workroom, a
toilet and a storeroom are on the ground floor. The bathroom, another workspace and three bedrooms are on the
upper floor. From one of these rooms, a stairway leads to
a gallery that provides access to the mechanical service
room, which is located in the attic. The mechanical
service room hosts the entire building services
installations.
building's heating energy demand, and this even prior to
the introduction of the EnEV regulations on energy
conservation. Along with the WeberHaus Company, the
project involved several enterprises specializing in
services-engineering and construction-engineering. The
ultra-low-energy building is an advanced type of the
formerly produced low-energy building. In addition, this
demonstration project was to prove that it is indeed
possible to develop and build prefabricated dwelling
houses, which combine very low heating-energy
demands and a high level of amenity. As a high standard
of thermal insulation and efficient building-services
engineering are usually not that much appreciated (and
paid for) by the purchaser, as are an exclusive
architectural approach and extravagant interior
furnishings, some cost-effective type of construction had
to be favored. Besides, the objectives mentioned above,
minimizing the primary energy input for production and
construction was another focal point of this project.
Objectives
Building construction
With their project "Weber 2001", WeberHaus (a
manufacturer of prefabricated buildings) followed the
objective
of
developing
building
The building was raised as a prefabricated construction.
The walls are insulated with a 160 mm layer of mineral
wool between the wooden posts. At the outside of the
wall, a 60 mm multilayer board was applied in order to
avoid thermal bridging in the area of the timber posts,
and to receive the exterior finish (U = 0.20 W/m²K). Parts
Project
concepts with expected energy demands that were to
remain clearly below the future requirements to a
of the external walls were not plastered, but sheathed
with timber (U = 0.19 W/m²K). The mineral-fibre
insulating board between the rafters is 200 mm thick.
Below the rafters, there is another 40 mm insulation layer
(U = 0.17 W/m²K). The basement ceiling is a wood
construction. The insulating board between the timber
beams is 200 mm thick. Above the timber beams, there is
a particleboard with a 30 mm rigid foam board. The
flooring was applied above a 60 mm screed layer
(U = 0.14 W/m²K). Thermopane double-glazing was used
for the windows (U = 1.4 W/m²K).
Technical systems
to be supplied to the habited rooms. The system may be
switched off by the users, and its capacity can be
adjusted in three steps. If an occupant opens a window,
the operation will be automatically interrupted.
The control functions (individual space heating control,
locking the radiators and the ventilation system, controls
of the lighting system including louvers and blinds) were
implemented by means of a decentralised installation
bus. To support the user, a central bus-operation and
information tableau was installed.
A gas condensing water heater with 11 kW power input,
which can be reduced to 3.5 kW, runs the heating
installation. The condensing boiler feeds an 800 liter
combined storage, which contains a 150 l integrated
service-water reservoir. As required by the situation, this
storage can be loaded with energy at different levels. A
12 m² solar collector field on the 25° inclined southern
roof supports heat supplies. The building is heated by
means of tubular radiators. The system is controlled by
way of central zone valves, allowing individual space
heating control. The central zones valves are controlled
via the internal building installation bus. They are
protected against unintentional heating while windows
are open (by means of window contacts). Besides, the
building has PV modules with a total area of 8.7 m². The
direct current thus produced is turned into alternating
current; it is fed into the net of the local energy provider.
A mechanical ventilation system (including heat recovery)
was installed in the ultra-low-energy building. The
exhaust air that was extracted from bathroom, kitchen
and WC transfers part of its energy (by means of a plate
heat exchanger) to the intake air, which is then preheated
To ensure air tightness, the vapor barriers and the
roofing membranes were continued across the respective
prefabricated compounds and were fitted together on the
construction site. The air tightness n50 was measured in a
blower door test; the measured value amounts to
1.6 h-1.
Energy performance
Solar energy contributes to space heating and domestic
hot water. In the 1998/99 heating period, the measured
final energy consumption required for heating purposes
was 70.6 kWh/m²a. This figure includes the power
consumption of the heating circulation pump, namely
1.8 kWh/m²a. The balanced ventilation system required a
power input of 0.7 kWh/m²a. In addition to the solar
supports, heating of domestic hot water still required a
final energy input of 10.4 kWh/m²a. If the final energy
consumption rates are multiplied with the respective
primary energy factors, a total primary energy supply of
84.1 kWh/m²a results.
Consumption
Heating
Ventilation
Domestic hot
water
Total
Final
energy
[kWh/m²a]
Primary energy
[kWh/m²a]
61.2
0.7
18.3
2.1
10.4
11.4
72.2
84.1
Elaboration and evaluation of the energy concept and
implementation of the monitoring programme: Fraunhofer
Institute for Building Physics (IBP), Stuttgart.
Contact persons
Johann Reiß, Fraunhofer Institute for Building Physics
([email protected])
WeberHaus Company (www.weberhaus.de)
References
Planning tools
The building's annual heating energy demand was
calculated on the basis of the calculation procedures
prescribed in the 1995 regulations on thermal insulation
standards (when the building was planned, the 1995
thermal insulation regulations were in force). Calculations
of different variants were computed using the dynamic
simulation programme Suncode.
-
-
-
Innovative products
Building: www.weberhaus.de
Building installation bus: www.siemens.de
-
-
Financing
The research project was funded by the Federal German
Ministry for Economics and Technology (BMWi).
Project team
-
Manufacturer of the prefabricated building:
WeberHaus GmbH, Rheinau-Linx, Germany
Architect:
Architekturbuero Disch, Freiburg
www.iea-shc.org
-
Kluttig, H.; Erhorn, H. and Hellwig, R.: Weber 2001 Energiekonzepte und Realisierungsphase.
Report WB 92/1997 by Fraunhofer-Institut fuer
Bauphysik, Stuttgart (1997).
Hellwig, R. and Erhorn, H.: Primärenergieaufwand
fuer die Herstellung und Nutzung der Gebäude.
Report WB 93/1997 by Fraunhofer-Institut fuer
Bauphysik, Stuttgart 1997.
Hellwig, R. and Erhorn, H.: Primärenergieaufwand
fuer die Erstellung und Nutzung von
Wohngebaeuden in Holzfertigbauweise.
IBP short information no. 335 (1998).
DeBoer, J.; Erhorn, H. and Reith, A.: Weber 2001 Hauskonzepte im Praxistest - Erste Messergebnisse.
Report WB 94/1997 by Fraunhofer-Institut fuer
Bauphysik, Stuttgart (1997).
DeBoer, J.; Erhorn H. and Reith A.: Niedrig- und NullHeizenergiehaeuser im Praxistest – Erste
Messergebnisse.
IBP short information no. 352 (1999).
DeBoer, J.; Feuchter, M.; Reith, A. and Erhorn, H.:
Validierung der im Projekt Weber 2001 entwickelten
Energiekonzepte eines Niedrigenergiehauses und
eines Ultra-Niedrigenergiehauses anhand
durchgefuehrter Messreihen.
Report WB 112/01 by Fraunhofer-Institut fuer
Bauphysik, Stuttgart (2001).
Fertighaeuser im Wandel. Brochure by WeberHaus
company and Fraunhofer-Institut fuer Bauphysik,
Rheinau-Linx / Stuttgart (2001).
www.ecbcs.org
ISIS demonstration housing project in
Freiburg, Germany
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
Passive solar apartment block ISIS
- cross section Ground floor plan (top) and first floor plan (bottom) with pipelines
of the ventilation system
The project
The ISIS solar passive apartment block is situated in
the recently developed residential area, Vauban, a
former military barracks area in Freiburg. The fourstorey apartment building, which was built within one
year, has been occupied since its final completion in
June 02. The passive solar apartment block has nine
maisonettes and four one-storey dwellings with
heated floor areas from 77 to 145 m².
The construction of the owner-occupied flats was
commissioned by the building group ISIS.
49 % of the southern facade area consists of
windows. Each dwelling has access to spacious
balconies or terraces on the ground floor, which are
situated on the south side.
The entrances to the dwellings, situated on the north
side, are accessible from the open staircase via
access balconies, which are thermally separated from
the building.
The ground floor has thermal insulation towards the
cellar.
Most of the dwellings are connected to the wood fired
district heating system. Each of the dwellings is
equipped with a ventilation system with heat recovery.
Therefore the rooms are heated mainly with the
supply ventilation air.
One dwelling has a combined heating and ventilation
unit, which includes the air-to-air heat recovery and
an exhaust-air heat pump providing the back-up
heating of the supply air and the heating of the
domestic hot water.
Design data:
net heated floor area: 1370 m²
heated volume: 3564 m³
ratio of exterior surface to volume: 0.39
Objectives
The construction of the ISIS passive apartment building
adapts the energy-efficient residential building design
with passive house standard from the single-family
house to the multi-storey residential building. Superinsulation of the envelope and the windows, a
ventilation system with heat recovery and an airtight
envelope ensure a low heating demand. The use of
district heating, provided by renewable energy, for
domestic hot water heating and auxiliary space heating
results in a minimal primary-energy demand and
demonstrates a sustainable energy supply concept.
Building construction
Exterior walls: solid
lime-sandstone brick
17.5 cm
thermal insulation
28.0 cm
Roof: lightweight construction
thermal insulation
40.0 cm
Ceiling of cellar (cellar not heated)
cement screed
6.0 cm
sound insulation
5.0 cm
concrete
22.0 cm
thermal insulation
20.0 cm
Windows: triple-glazed high-performance
wooden frame, externally insulated
U value:
Exterior wall
0.13 W/(m²K)
Roof
0.11 W/(m²K)
Window
0.90 W/(m²K)
Ceiling of cellar
0.18 W/(m²K)
District
heating
ISIS passive solar apartment block - heating supply system with district heating and solar collector array
Technical systems
• District heating provided by a wood heating plant
ensuring domestic hot water supply and space
heating;
• Two-pipe system with individual heating of domestic
hot water via a heat exchanger in every dwelling;
• Ventilation system with heat recovery and back-up
heating of the supply air via hot water heat
exchanger;
• Radiators (hot water and electric) in bath room and
living room in some dwellings;
• Combined heating and ventilation units supplying
fresh air, air heating and providing domestic hot
water via a storage tank. ;
• 23 m² thermal solar collector array supporting the
central heating system - space heating and DHW;
• 5 kWP PV system, installed by 9 of the families of the
apartment block.
Energy performance
• Heat demand
Space heating:
13.2 kWh/(m²a)
(PHPP)
Domestic hot water: 12.5 kWh/(m²a) (EnEV2002)
• Yield of solar collector system: 300 kWh/(m²a)
(expected value)
• Electricity
Ventilation / fans: 5 kWh/(m²a)
(expected value)
controls / pumps: 1.7 kWh/(m²a) (expected value)
lighting and appliances: 27 kWh/(m²a)
(after VDI 3087)
Planning tools
The heating demand was calculated according to a
planing tool for passive houses (PassivHausProjektierungsPaket PHPP) taking the ventilation heat
recovery gains into account.
A major aspect of the building planning was to avoid
thermal bridges in accordance to DIN 4108 - Annex 2.
Costs and benefits
The positive experience made with a free-standing
passive houses has been adapted to the apartment
building.
Compact design, efficient thermal insulation,
minimising of heat bridges and airtight envelopes are
integral components for cost-optimised building of
passive apartment blocks.
Central or individual systems can be used for
ventilation and heat supply for space heating and
domestic hot water, to allow for individual user
requirements.
While comfortable living conditions are ensured, the
operating costs for heating in passive apartment
blocks are low, since the heating consumption is
reduced to 10% of that for conventionally
constructed, modern buildings.
The construction costs for the passive solar
apartment block amounted 1241 Euro/m² (for
construction and HVAC)t and costs for land and
planning). That is 9% more compared to building
constructed according to the standards of the German
energy-saving ordinance (Energieeinsparverordnung
EnEV).
Heat exchanger LOGOTERM for domestic hot water
Innovative products
Building envelope
Window and door:Fa. Klaus Müller, Lautenbach;
www.muellerlautenbach.de
Ventilation and cooling
Heat recovery unit: www.maico.de
Space heating and DHW:
District heating based on CHP(60% wood ship) and
solar collector
Combined heat and ventilation unit : www.maico.de
Thermal solar collector : Fa.Solvis, Braunschweig
www.solvis.de
Financing
The members of the building group were already
informed about energy-efficient passive building and
they deliberately decided on a passive house. Building
in a building co-operative makes cost optimisation
possible. A building co-ordinator and the estate agent’s
commission are avoided and building materials are less
expensive. Coping together with conflict situations
serves the common interest of the building group.
The building costs were financed by the owners,
supported by the German governmental subsidy
„Eigenheimzulage“ and to deal in favourable credit
terms by the KfW (Kreditbank für Wiederaufbau KFW40/60 CO2-Reducing program).
The monitoring was funded by the DBU - Deutsche
Bundesstiftung Umwelt
www.iea.shc.org
Installation of the combined heating
and ventilation unit
Project team
Architect: Architekturbüro Meinhard Hansen (project
manager H. Bollwerk), Freiburg
www.meinhard-hansen.de
Building Services Technology: solares bauen
Ingenieurgesellschaft für
Energieplanung mbH, Freiburg
www.solares-bauen.de
Electricity: Planungsgruppe Burgert, Ingenieurbüro
für Elektrotechnik, Schallstadt
Monitoring: Fraunhofer Institute for Solar Energy
Systems ISE, Freiburg
www.ise.fraunhofer.de
Contact person
Meinhard Hansen, Architect
([email protected]
Christel Russ, Fraunhofer ISE
([email protected]
Literature and links
www. ise.fraunhofer.de
www.phasea.de
www.ecbcs.org
Demonstration Houses in
Hannover-Kronsberg,
Germany
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
view from south, roofs with solar collectors and low intensity planting
cross section, view from west
horizontal projection
supply-air and exhaust-air valves are indicated
Passive House standard
The conception of passive houses was developed in the late eighties. Meanwhile the super insulated houses with mechanical ventilation and heat recovery proofed to provide high thermal comfort with
extreme low specific heat energy consumption of about 15 kWh/
(m2 a). This is an energy conservation of about 75% compared to
conventional buildings.
The project
The 32 terraced houses in Hannover Kronsberg are arranged in
four rows with eight houses each row. This arrangement offers the
advantage of reduced envelope surface area to volume ratio. The
houses are type buildings which are available in three sizes with 79,
97, and 120 m2 floor area respectively.
The main intention of this project was to show, that heat supply in
passive houses can be realized by warming up the supply air of the
balanced ventilation system. So these houses have no conventional
heating system with radiators, except one in the bathroom.
The houses were built by a construction contractor to be reselled for
private use. The intention was to provide room for young families.
The dwellings were partially funded by the Community of Hannover.
The Passive House Project in Hannover Kronsberg was a registered EXPO 2000 project (Cost efficient Climate Neutral Passive
Houses, Reg. No. NI244).
Construction
Walls and roofs are made of light-weight wooden construction with Uvalues of Uwall= 0.13 W/(m²K) and Uroof = 0.10 W/(m²K). The core of
the building, the cross-walls and end-walls are made of prefabricated
concrete elements. This modular construction allowed cost reduction,
so it was possible to achieve pure building costs that are as low as
for conventional buildings.
Good airtightness of the building envelope is an essential precondition for passive houses. Many details of the construction had to be
revised to fulfill the augmented specifications e.g. flash strips to join up
window-frames to the wall are necessary. The airtightness was
checked by means of a "blower door test", and reached a residual
air change rate at 50 Pa of n50 = 0.3 ac/h in average.
SAH
in each rowon
house:
view from south withInstallations
solar collectors
top of the roof
Left: Solar hot water storage and supply-air heater (SAH).
Right: Mechanical ventilation system with heat recovery.
Controlled mechanical ventilation with heat recovery
requires air- tightness
The passive house conception includes controlled air supply and
exhaust-air extraction with heat recovery. The above mentioned
excellent air-tightness of the building envelope is an essential precondition to the passive house standard, so that all the air change
for ventilation takes place via the high-efficient counterflow air-toair heat exchanger with a heat recovery rate of 80 %. Ventilation
heat losses are thus reduced significantly.
The controlled ventilation system supplies the dwelling rooms all
around the clock with fresh air warmed up in the heat exchanger.
The inhabitants MAY open doors and windows, but they DO NOT
NEED to accomplish ventilation through windows during the
heating period. The length of the air ducts was designed to be as
short as possible for architectual as well as for cost and efficiency
reasons (pressure drop and heat losses).
The heating of the building during the heating period (November
to March) is performed by a supplementary water/air heater
placed after the heat recovery, which heats up the supply air. The
only servicable part of the ventilation system are the air filters,
which have to be changed regularly. Artificial humidification of air is
not necessary. If humidity of air drops too low in winter, the
inhabitants are advised to reduce the air exchange rate below the
designed value of 120 m3 /h.
Infrared thermography test
Enery supply system
All houses are connected to a grid of district heat supply
which is fed by a combined heat and power machine. In
addition flat plate thermal solar collectors and a thermal
storage tank in each house are used for domestic hot
water production in summer.
The connection to the grid is implemented separately for
two rows of eight houses each respectively. All houses
are connected via a heat load line from the connector.
This line supplies the hot water tank of the solar thermal
system in each house, if not enough heat from the sun is
available. Moreover it supplies the water-to-air heater to
provide space heating.
Househould appliances
Almost all dwellings are equipped with dish-washer and
the washing machine connected to the domestic hot water
supply to avoid electrical heat production as much as
possible. All inhabitants were advised to provide their
households with energy saving electric appliances e.g.
light, cooling and freezing, dish-washer, and washing
machine. With the aid of a questionnaire the energysaving potential was evaluated. The use of low energy
appliances was funded by a repayment by the
construction contractor.
Passive solar gains and shading in summer
Most passive houses have its main windows directed to
south, so daylighting is provided by direct solar radiation
most time of the day. In winter, solar gains through
windows cover about one third of space heating energy
demand.
In summer, a manual-driven shading system protects the
rooms from too high temperatures. Besides this, the highquality thermal insulation in combination with the large
internal masses (concrete) help to keep the temperatures
in summer on a moderate level, if cross ventilation during
the night is applied.
Costs
Modular construction of terraced houses and multi-storey
flats allow to achieve pure building costs that do not
extend the costs of conventional buildings. This type of
construction offsets the extra expenditure for insulation
and ventilation system almost completely. Modular
construction means a high degree of prefabrication of the
various structural elements, a low number of different
elements with improved quality, sophisticated logistics and
a short construction time. This cost reduction provides for
a broad introduction of passive houses into the market.
Planning tools
The planning process of passive houses is assisted by the PHPP (passive-house-planning package). This is a
spreadsheet calculation tool, which is based on the EN 832. Some calculations and assumptions, such as air-tightness,
heat-recovery, internal gains, solar gains and shading etc. are treated more sophistically. The reason for this is, that some
assumptions in national standards are not valid with respect to passive houses. It is essential in this case to calculate with
higher accuracy to get reasonable results. The PHPP is available at Passive House Institute (see below).
Scientific research studies
Within the CEPHEUS project (Cost Efficient Passive Houses as European Standards) funded by the European
Commission, the temperatures and heat energy consumption was measured to show the reliability of the passive-house
conception. See the following publications:
Feist, W., Peper, S., Oesen, M., CEPHEUS-Projektinformation Nr. 18, Klimaneutrale Passivhaussiedlung HannoverKronsberg, published by the Stadtwerke Hannover, 2001.
Peper, S., Feist, W., Kah, O., CEPHEUS-Projektinformation Nr. 19, Klimaneutrale Passivhaussiedlung HannoverKronsberg, Meßtechnische Untersuchung und Auswertung, published by the Stadtwerke Hannover, 2001.
Kaufmann, B., Feist, W., Vergleich von Messung und Simulation am Beispiel eines Passivhauses in HannoverKronsberg. CEPHEUS Projektinformation Nr. 21, published by the Stadtwerke Hannover, 2001.
Schnieders, J., CEPHEUS – Wissenschaftliche Begleitung und Auswertung, Endbericht, CEPHEUS Projektinformation Nr.
22, Passivhaus Institut, Darmstadt, 2001, see as well at www.cepheus.de
Peper, S., Feist, W., Klimaneutrale Passivhaussiedlung Hannover-Kronsberg. Analyse im dritten Betriebsjahr. Endbericht
im Auftrag der Stadtwerke Hannover. Darmstadt, April 2002.
Danner, M., Institut für Umweltkommunikation, Universität Lüneburg, Nutzererfahrungen in der Passivhaussiedlung in
Hannover-Kronsberg. Contribution to the 7. International Passive House Conference, Hamburg 2003, Conference
Proceedings in German, Passivhaus Institut, Darmstadt, 2003
A further CEPEUS publication in english is available from Stadtwerke Hannover.
Illustrations: The cross section and horizontal projections originate from the architects Rasch & Partner, see below.
All photographs PHI.
Architects: Rasch & Partner, Volkmar Rasch and Petra Grenz, Steubenplatz 12, 64293 Darmstadt
The energy supply and ventilation conception was developed by inPlan, Ingenieurbüro,
Norbert Stärz, Bahnhofstraße 49, 64319 Pfungstadt, Germany, email: [email protected]
Scientific work, consulting and quality assurance management was done by
Passivhaus Institut (PHI), Dr. Wolfgang Feist, Rheinstr. 44-46, D-64283 Darmstadt, Germany
Phone: +0049 (0) 6151 / 826 99-0 Fax:
+0049 (0)6151 / 826 99-11
internet: www.passivehouse.com
email:
[email protected]
Funding
Scientific work about the Kronsberg passive houses was done within the CEPHEUS project, which was funded by the
European Commission, Directorate-General XVII, Energy, Thermie, Project Number BU / 0127 / 97
Duration from 1/1998 to 5/2001.
www.iea-shc.org/task28
www.ecbcs.org
Kassel,
Germany
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
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Passive House standard
The conception of passive houses was developed in the late eighties.
Meanwhile the super insulated houses with mechanical ventilation and heat
recovery proofed to provide high thermal comfort with extreme low specific
energy consumption for space heating of about 15 kWh/(m2a).
The main intention of this project was to show, that the conception of
passive houses works with low-income housing in an urban environment
even under unfavorable orientation and shading conditions, and can be
realized at moderate costs.
The project
The apartment houses were built by the GWG, a local housing company for
low-income people. The intention was to provide space for young families.
The dwellings are rented to the inhabitants.
The two apartment buildings with 40 dwellings in total are situated in the
redeveloped urban area of Marbachshöhe in Kassel. Up to the late nineties
military barracks have been located there. In this brochure one of the two
buildings (realized by HHS1) and ASP2)) with 23 dwelling units is described
thoroughly. This appartment house has three main storeys with 7 dwelling
units each. Two units are located towards south one floor higher. All 23
dwelling units have three rooms, bath and kitchen on an average area of
72 m2. To save costs, no basement is available but each dwelling has it's
storage room in the stair case.
As the development plan prescribed the main orientation of the buildings to
be east / west, only two dwellings per storey are south oriented. So the
living-rooms with balcony face towards west. To avoid overheating of the
rooms in summertime temporary shading by shutters is provided. Low total
solar gains during winter are compensated by the low A/V ratio and the
high thermal insulation standard.
Construction
The construction of the exterior walls is massive by sand-lime bricks
(thickness of 17.5 cm) with a thermal insulation layer made of expanded
polystyrene (EPS, λ = 0,040 W/(mK)), thickness of 30 cm. The flat roof is
made of concrete with a 35 cm thick EPS-layer on top. Above this a green
flat 'flying roof' and some roof terraces are located. The lowest floor has a
33,5 cm EPS layer on top of the concrete plate. The outside walls of the
ground floor have a thermal separating layer of tight PU-recycling-foam
material (λ = 0,075 W/(mK)) to prevent from thermal-bridge effects.
Mechanical ventilation with heat recovery
The passive house conception includes controlled air
supply and exhaust extraction with heat recovery. In this
building a 'semi-central' ventilation system was realized:
The heat recovery units (air-to-air heat exchanger) are
located centrally on the flat roof. Inside the dwellings only
few components of the ventilation system are located
above the suspended ceiling and in the shaft. These are
the silencers, the supplementary water-to-air heater, and
the fans. So each inhabitant has the authority over the
temperature and air exchange rate. The heat recovery is
centralized to increase efficiency and to save costs.
Every six to eight dwelling units are connected to one of
the central heat recovery units.
Instruction for inhabitants
All inhabitants were instructed in the use of the controlled
ventilation system. The inhabitants MAY open windows,
but they DO NOT NEED to accomplish ventilation
through windows any longer. Only air filters must be
changed regularly by the inhabitants.
Controlled air supply requires air tightness
Controlled air supply and exhaust extraction with heat
recovery requires good airtightness of the total envelope
as an essential precondition to the passive house
standard. The airtightness of the building envelope was
checked by means of a "blower door test", and reached a
residual air change rate at 50 Pa of n50 = 0.35 ac/h. This
is not a misprint: the houses are intentionally
extraordinary airtight.
The supplementary room heating during the main
winter(November to March) is performed by
supplementary water-to-air heater of the supply air after
the heat recovery which is connected directly to the heat
supply line in the house. Artificial humidification of air is
not necessary.
Energy performance
The house is connected to the grid of the local district
heat supply. The connection (heat exchanger) to the grid
has an additional heat storage tank (800 liters of hot
water) to manage peak loads of hot water supply. The hot
water installation is equipped with a circulation line.
central heat recovery unit
decentral installation in
each dwelling
Costs
The building costs amount to about 90 000,- EURO per
dwelling unit (72 m²). The extra costs to reach passivehouse standard were about 8 000,- EURO per unit.
The houses were funded in the framework of low-income
housing programs as all council houses in Germany For
this reason the building cost were restricted to an upper
limit. Nevertheless the passive house features could be
realized within this restricted budget.
All dwellings have the possibility to connect the dishwasher and the washing machine with the domestic hot
water (DHW) supply to save electricity as much as
possible. Special water cocks were installed to achieve
reduction of hot water consumption.
The common corridors are completely equipped with
energy efficient lighting. All other appliances are in the
ownership of the inhabitants. They were advised how to
reduce the energy consumption of their household
appliances.
Infrared thermograpy test
Planning tools
The planning process of passive houses is assisted by the PHPP (passive-house-planning package). This is a
spreadsheet calculation tool, which is based on the EN 832. Some calculations and assumptions such as air-tightness,
heat-recovery, internal gains, solar gains and shading etc. are treated more sophistically. The reason is, that some
assumptions in national standards (e.g. DIN 4108) are not valid with respect to buildings with a very low energy
consuption especially passive houses. It is essential in this case to calculate with higher accuracy to get reasonable
results.
Scientific research studies:
Within the CEPHEUS project (Cost Efficient Passive Houses as European Standards) the temperatures and heat energy
consumption was measured to show the reliability of the passive-house conception in the framework of low income
housing, see the following publications:
Fingerling, K.-H., Feist, W., Otte, J., Pfluger, R. 'Konstruktionshandbuch für Passivhäuser', Teil 1 des Forschungsberichts
zum Projekt: 'Das kostengünstige mehrgeschossige Passivhaus in verdichteter Bauweise' gefördert mit Mitteln des
Bundesamtes für Bauwesen und Raumordnung, Passivhaus Institut, Darmstadt, 2000.
Pfluger, R. , Feist, W., Kostengünstiger Passivhaus-Geschosswohnungsbau in Kassel Marbachshöhe, Endbericht,
CEPHEUS-Projektinformation Nr. 16, Passivhaus Institut, Darmstadt, 2001
Schnieders, J., CEPHEUS – Wissenschaftliche Begleitung und Auswertung, Endbericht, CEPHEUS Projektinformation Nr.
22, Passivhaus Institut, Darmstadt, 2001, see as well at www.cepheus.de
Pfluger, R. , Feist, W., Sommerliches Innenklima im Passivhaus-Geschoßwohnungsbau, Meßtechnische Untersuchung
und Auswertung des sommerlichen thermischen Verhaltens eines Passivhaus-Geschoßwohnungsbaus in KasselMarbachshöhe, CEPHEUS-Projektinformation Nr. 42, Passivhaus Institut, Darmstadt, October 2001.
Drawings on page 1 and 2 originate from the architects, HHS and ASP, see below.
Drawings on page 3 originate from innovatec. All photographs PHI.
Architects:
1)
2)
ASP, Planungs- und Bauleitungsgesellschaft mbH, Architektur und Stadtplanung, Emilienstraße 4, 34121 Kassel
Hegger, Hegger, Schleiff, HHS Planer + Architekten BDA, Habichtswalder Straße 19, 34119 Kassel
The energy and ventilation conception was developed by innovaTec Energiesystem GmbH,
Im Graben 5, 34292 Ahnatal-Weimar, email: [email protected]
Scientific accompanying work and consulting was done by Passivhaus Institut (PHI),
Dr. Wolfgang Feist, Rheinstr. 44-46, D-64283 Darmstadt, Germany
Phone: +0049 (0) 6151 / 826 99-0
Fax:
+0049 (0)6151 / 826 99-11
internet: www.passivehouse.com
email:
[email protected]
Funding:
The conceptional project-phase was funded by the German 'Bundesamt für Bauwesen und Raumordnung' under contract
No. B15-800198-15. See above: 'Konstruktionshandbuch für Passivhäuser'.
Additional scientific research about the Marbachshöhe passive houses was done within the CEPHEUS project, which was
funded by the European Commission, Directorate-General XVII, Energy, Thermie, Project Number BU / 0127 / 97 Duration
from 1/1998 to 5/2001 and the 'Hessische Ministerium für Umwelt, Landwirtschaft und Forsten'. Funding within the
framework of IEA Task 28 (documentation) came from the german Bundesministerium für Wirtschaft und Technologie
(BMWi).
www.iea-shc.org
www.ecbcs.org
3-Litre Townhouse
Celle, Germany
IEA-SHC Task 28 / ECBCS Annex 38:
Sustainable Solar Housing
Building characteristics
Building volume Ve
654 m³
A/V
0.70 m-1
Usable floor area AN
209 m²
The Project
The detached single-family house was built in a
newly developed area at the outskirts of Celle in
2001. The city of Celle is located about 30 km north
of Hanover. To the south, this developing area
abuts upon a recreation forest, and to the north
upon an existing residential area. The 1 ½ storey
building has a surface-to-volume ratio A/V of
0.70 m-1 and a usable floor area AN of 209 m². The
living room, the study, the kitchen, and the utility
room are located on the ground floor. The top floor
hosts five rooms and a bathroom. The building was
raised by a major local manufacturer of
prefabricated buildings as a lightweight timber
construction.
Objectives
The manufacturer of this prefabricated house is
expecting a growing demand for residential
buildings with an extremely low energy demand in
the
near
future.
This
is
why the company developed this prototype building,
designated 'Townhouse', as a 3-litre house. Lowenergy buildings with an annual primary energy
demand of less than 34 kWh/m²a for heating
(inclusive of auxiliary energy for pumps and fans)
are referred to as '3-litre houses'. This corresponds
to the primary energy content of 3 litres of heating
oil. To succeed in a competitive market, strict
economic criteria had to be obeyed when
developing the house. In future, the manufacturer
will distribute this type of building all over Germany.
Building construction
The exterior walls are lightweight timber stud
structures. The mineral-fibre insulation layer
inserted between the vertical timber studs is
200 mm thick. An additional 85 mm polystyrene
insulating layer was applied to the outside of the
wall. This layer was plastered in the ground floor
area, but sheathed with timber in the top floor area.
The wall has a U-value of 0.15 W/m²K. The roof
was insulated with a 240 mm mineral-fibre layer
between the rafters (U = 0.18 W/m²K). The building
has no cellar. The concrete floor slab of the building
was provided with a 120 mm rigid-foam insulation
board below the screed (U = 0.31 W/m²K). The
wooden windows have a double thermal insulation
glazing (UW = 1.6 W/m²K); the interspace is filled
with argon gas. The total energy transmittance of
the glazing is equal to 0.58.
To ensure air tightness, a polythene sheet was
applied to the internal side of the walls. The outside
of the walls was provided with a roofing membrane;
all junctions were hermetically sealed. The air
tightness n50, which was determined in a blowerdoor test, amounts to 0.65 h-1.
Technical systems
The heat required for townhouse space heating and
domestic hot water is generated by a gascondensing water heater, which can be operated
between 3.5 and 11 kW. The heat is distributed to
the spaces of the house by means of a single-room
controlled, water-bearing floor heating system on
the ground floor, and through radiators located on
the top floor. There is an individual space heating
control in each room with underfloor heating. The
spaces are equipped with indoor-air temperature
sensors that control the servomotors of the heating
circuits, thus influencing the throughput of water. In
the other radiator-heated spaces, the indoor-air
temperature is controlled by means of thermostatic
valves.
The necessary air change is ensured by means of a
balanced ventilation system (with heat recovery).
This system is provided with a high-efficiency
counterflow heat exchanger. Re-heating of the
supply air was therefore considered unnecessary.
As a rule, the ventilation system is run at stage 2.
Depending on demand, the system can be manually
switched to setback operation (stage 1) or to
intensive ventilation (stage 3). There is also a timeprogramme that allows the fan stages to be timed in
advance.
The domestic hot water is heated in a 300-litre
storage tank by the gas condensing water heater.
The entire technical systems were installed in the
utility room on the ground floor.
Energy performance
The calculated primary energy demand for heating
amounts to 26.9 kWh/m²a. This value includes the
auxiliary energy required for heat generation and
heat distribution. The ventilation system has a
primary energy demand of 6.6 kWh/m². The total
primary energy supply for domestic water heating is
equal to 32.8 kWh/m²a. The calculated primary
energy demand for heating and venting is
33.5 kWh/m²a. This corresponds to the primary
energy content of 3 litres of heating oil per m² and
year. The total primary energy supply for the
building amounts to 66.3 kWh/m²a; this value is
about 40 % less than the permissible value of
110 kWh/m²a that is specified in the current German
regulations on energy conservation (EnEV)
Consumption
Heating
Ventilation
DHW
Total
Final
energy
[kWh/m²a]
21.6
2.2
28.3
52.1
Primary
energy
[kWh/m²a]
26.9
6.6
32.8
66.3
Space heating and DHW:
Condensing boiler: www.junkers.com
Financing
The elaboration of the concept was funded by the
German Federal Ministry of Economics and Labour
(BMWA).
Project team
Manufacturer of the prefabricated building:
Haacke + Haacke GmbH + CO. KG,
Am Ohlhorstberge 3, D-29202 Celle
Architect:
Dr. Stauth, Braunschweig
Planning tools
The energy demand for heating, ventilation and
domestic hot water was computed by way of the
calculation routine that is applied in order to verify
the energetic requirements specified in the German
regulations on energy conservation (EnEV).
Evaluation of the concepts and performance of the
monitoring programme:
Fraunhofer Institute for Building Physics, Stuttgart.
Costs
-
The sales price for the ready-for-occupancy
prefabricated house amounts to € 268,600. This
price does not include the costs for the foundations.
-
Innovative products
Literature
Ventilation:
Heat recovery unit: www.jestorkair.nl
Reiss, Johann; Erhorn, Hans: The Celle
3-litre-house - validation by measurements IBP
Report WB 123 (forthcoming).
www.iea-shc.org
Contact persons
Johann Reiß, Fraunhofer Institute for Building
Physics ([email protected])
Manufacturing Company:
Haacke + Haacke GmbH + CO. KG
([email protected])
www.ecbcs.org
3-Litre Twin Houses
Ulm, Germany
IEA-SCH Task 28 / ECBCS Annex 38:
Sustainable Solar Housing
Basement
First floor
Top floor
Second floor
Building characteristics
Building volume Ve
556 m³
A/V
0.62m-1
Usable floor area AN
178 m²
Cross section
The project
In collaboration with major manfacturers of building
materials, the municipal housing society (NUWOG) of
the city of Neu-Ulm, Germany, raised 3 semi-detached
buildings that were designed as 3-litre houses within
the framework of a model project located in Ulm. The
term '3-litre house' applies to low-energy buildings,
whose annual primary energy demand for heating
figures below 34 kWh/m²a (including the auxiliary
energy required for pumps and fans). This corresponds
to a primary energy content of 3 litres of fuel oil. The
buildings were optimized with regard to their energetic
performance and to construction costs, offering
maximum amenity in conjunction with a maximum of
liberty regarding the floor plan and possible uses. On
the first floor, there is a small draught-lobby, the
stairway, the kitchen and a south-facing living room, a
toilet with a shower and an additional room for uses as
required. The bedrooms and a large bathroom are
situated on the second floor. The top floor hosts a
studio giving access to the south terrace and an exit to
the north terrace. In all the buildings there is a
basement. Covered courtyards are located between the
buildings. During two heating periods, the Fraunhofer
Institute of Building Physics will validate the energy
concept of these buildings that were completed and
occupied at the end of 2003.
For the construction of these 3 semi-detached houses,
the municipal housing society was awarded the
builders' prize 2004 for "High quality – Affordable
costs"by the Association of German Architects.
comprising fans, filters, an extract-air heat pump, a
cross-flow plate heat exchanger and a hot water tank
with an electric heating rod, is integrated in one
compact device which was installed in the bathroom.
The outdoor air is drawn in from above the roof. While
the air is passing into the habitable rooms, the crossflow plate heat exchanger will transfer part of the heat
contained in the extract air to the fresh air.
Objectives
The model project was to demonstrate how innovative
technologies and innovative external wall blocks, in
conjunction with an optimally selected building
orientation, make it possible to construct monolithic
buildings that achieve the standard of a 3-litre house
without any thermal insulation being applied to the
external walls. The buildings are referred to as "Houses
for all periods of life" because they can be adapted to
meet the occupants' changing needs and wants
concerning space and habitation during their different
periods of life. Initially designed as a spacious, open
home, the house can be broken up into zones as time
goes by. It is possible to separate the first floor to obtain
a supplementary, self-contained flat.
Building construction
The buildings have a south-east orientation of
approximately 25°. The surface-to-volume ratio is
0.62 m-1, with a gross volume of 556 m³. The building's
usable floor area is 178 m², the floor space is 142 m².
The external walls are monolithic, 42.5 cm brickwork
constructions (U=0.20 W/m²K). The windows are made
of triple glazing and wooden frames (Uw=0.80 W/m²K)
with high-performance thermal insulation. The horizontal roof is a lightweight construction with high web
girders between which a mineral wool insulation was
inserted (U=0.08 W/m²K). A 20 cm layer of rigid foam
insulation (U=0.11 W/m²K) was applied to the lower
surface of the concrete basement ceiling. Special
importance was placed upon the building's airtightness.
Appropriate sealing strips were used to seal the
connections between the window frame and the wall.
The n50 – values that were measured in the blower-door
test range below 0.6 h-1.
The air is further heated up by the heat pump. The
exhaust air will be extracted from the wet rooms
(kitchen, bathroom and toilet) to be then passed on
through the cross-flow plate heat exchanger. This is
where it cools down by transferring part of its heat to
the supply air. The heat pump's evaporator unit will cool
the air still further. The exhaust air will be discharged
via the roof. In some residential units though, radiators
that also receive energy from the compact device were
installed in the bathroom. The heat pump also heats up
the service water. In case of insufficient power output,
the electric heating rod can be used for reheating the
water. To support domestic water heating (and space
heating, as well) a supplementary solar heating system
with a collector area of 5 m² was installed.
Technical systems
Energy performance
The buildings are heated by means of a warm air
heating system. The entire building services equipment
According to the EnEV (German regulations on energy
conservation) method of computation, the application of
Scheme of installation
which is required by law, the calculated primary energy
demand for heating and ventilating including the
auxiliary energies amounts to 23 kWh/m²a. This figure
implies solar supported heating, and the cross-flow
plate heat exchanger is assumed to have a heat
recovery rate of 80 %. Further, all thermal bridges were
minimized in such a way that no allowances were
required when calculating the transmission heat losses.
The calculated value of 23 kWh/m²a corresponds to a
heating oil equivalent of 2.1 litres of heating oil per
square meter per year. Domestic water heating (DHW)
requires a primary energy input of 16 kWh/m²a
including the solar supports. Accordingly, a primary
energy total of 39 kWh/m²a will cover heating,
ventilating and domestic hot water including the
required auxiliary energies.
Planning tools
During the planning stage, the different options for the
building's optimization were evaluated by means of the
monthly balance method laid down in the regulations on
energy conservation (EnEV). The calculations required
for minimizing heat losses due to thermal bridging were
performed by means of TRISO, the three-dimensional
thermal bridges programme developed at the
Fraunhofer Institute of Building Physics (IBP).
Costs
The building's costs per unit floor area (without carport,
floor coverings, interior painting work, costs for
development and land) amount to 1050 €/m². This
value corresponds to the cost limit for local authority
housing in Bavaria.
Marketing strategy
The twin houses were built by the Neu-Ulm
Wohnungsgesellschaft GmbH (NUWOG), a communal
housing construction firm owned by the city of Neu-Ulm,
possessing a stock of almost 2,500 flats (either owned
or administrated). Sales strategies for the six halves of
the three twin houses included both traditional methods
(e.g. press advertisements, on-site inspections, sales
literature etc.) and unconventional procedures, namely
members of the "construction team“ who had
accompanied the building project engaging in sales
promotion activities. For instance, the building society
Allianz-Dresdner Bauspar-AG introduced this project on
a national scale to interested visitors from the trade on
the occasion of the "Bad Vilbel Talks" staged by this
company. Further, the manufacturer of building bricks
Ziegelwerk Bellenberg has used several occasions
during the building brick industry's trade conferences to
draw the attention to the exceptional qualities of this
pilot project. Last but not least, the City of Ulm
(represented by the mayor in charge of urban
construction projects) has not ceased to propagate the
project as an excellent example of residential building in
these times of severer requirements with regard to
ecological concepts, being fully aware of hosting a very
special residential building in its city limits.
Innovative products
Building envelope
Wall: Bricks (Planziegel SX plus): www.bellenberger.de
Window: Passive house windows: www.freisinger.at
Roof: Insulating rafters (PN-Daemmsparren): www.1akmh.de
Heating and ventilating
Space heating and heat recovery unit:
VITOTRES 343: www.viessmann.de
Financing
The validation measurements scheduled to be
performed after the occupancy of the dwellings will be
funded by the housing society of the city of Neu-Ulm
(NUWOG), by the Supreme Building Authority in the
Bavarian State Ministry of the Interior of the free state
of Bavaria (Germany), and by the Ministry of the
Environment and Transport of the federal state of
Baden-Wuerttemberg, Germany.
Project team
Builder:
NUWOG Neu-Ulmer Wohnungsbaugesellschaft mbH,
Johannisstrasse 12, D-89231 Neu Ulm
Architect:
G.A.S.-Architektur und Stadtplanung
Sahner + Sahner, Ludwigsstrasse 57,
D-70176 Stuttgart
Construction supervision:
Planungsgruppe Sterr – Ludwig,
Arnegger Strasse 1, D-89134 Blaustein
Building services planning :
Planungsbuero Bohnacker,
St.-Antonius-Str. 2, D-88601 Schmiechen
Scientific monitoring of the execution of the works and
performance of the validation measurements:
Fraunhofer-Institut fuer Bauphysik,
Nobelstrasse 12, D-70569 Stuttgart
Construction team:
Allianz Dresdner Bauspar AG,
Am Sonnenplatz 1, D-61116 Bad Vilbel;
Dresdner Bank AG in Ulm.
-
BAYOSAN Wachter GmbH & Co. KG,
PO Box 1251, D-87539 Hindelang/ Allgaeu
-
Freisinger Bau- & Moebeltischlerei GmbH & Co.
KG, Wildbichlerstrasse 1, A-6341 Ebbs
-
Viessmann Werke GmbH & Co.,
D-35107 Allendorf/ Eder
-
Ziegelwerk Bellenberg Wiest GmbH & Co. KG,
Tiefenbacher Str. 1, D-89287 Bellenberg
The construction team cooperated from the very
beginning, performed joined marketing measures and
accompanied the building process by giving
professional support.
Contact persons
Georg Sahner, architect
([email protected])
Johann Reiss, Fraunhofer-Institut fuer Bauphysik
([email protected])
NUWOG Neu-Ulmer Wohnungsbaugesellschaft mbH
([email protected])
Technical literature
Reiss, Johann; Erhorn, Hans: 3-Liter-Haus
Modellprojekt OE.KOM.MOD in Ulm/ Soeflingen.
Concept development and validation by measurements.
IBP Report WB (to be published on completion of the
validation measurements)
www.iea-shc.org
www.ecbcs.org
3-Litre Urban Villa
Celle, Germany
IEA-SHC Task 28 / ECBCS Annex 38:
Sustainable Solar Housing
Building characteristics
Building volume Ve
599 m³
A/V
0.69 m-1
Usable floor area AN
191.8 m²
The project
The detached, single-family house was raised in
2003. It is situated in a newly developed area at the
outskirts of Celle. The city of Celle is located about
30 km north of Hanover. To the south, the
developing area abuts upon a recreation forest and
to the north upon an existing residential area. The
one-and-a-half-storey building has a surface-tovolume ratio A/V of 0.69 m-1. The usable floor area
AN amounts to 191.8 m². The ground floor hosts the
living room, the kitchen, a study and a
housekeeping room; on the top floor, there are a
bathroom, another housekeeping room and three
more bedrooms. The building was raised by a local
manufacturer of prefabricated buildings as a
lightweight timber construction.
Objectives
The manufacturer of this prefabricated house is
expecting a growing demand for residential
buildings with an extremely low energy demand in
the near future. This is why the company developed
this prototype building, designated 'Urban villa', as a
3-litre house. Low-energy buildings with an annual
primary energy demand of less than 34 kWh/m²a for
heating (inclusive of auxiliary energy for pumps and
fans) are referred to as '3-litre houses'. This
corresponds to the primary energy content of 3 litres
of heating oil. To succeed in a competitive market,
strict economic criteria had to be obeyed when
developing the house. In future, the manufacturer
will distribute this type of building all over Germany.
Building construction
The exterior walls are lightweight timber stud
structures. The mineral-fibre insulation layer
inserted between the vertical timber studs is
200 mm thick. An additional 60 mm insulating level
with a mineral wool infill was applied on the inside.
In the ground floor area, the external face of the wall
was covered with cleaving tiles; in the top floor area,
it was covered with profiled timber. The roof was
insulated with a 240 mm mineral-fibre layer between
the
rafters
(U = 0.14 W/m²K); below the rafters, there is a
60 mm layer of mineral wool. The building has no
cellar. The floor of the building was provided with a
120 mm rigid-foam insulation board both above and
below the concrete slab (U = 0.15 W/m²K). The
windows were provided with passive house frames
and have triple thermal insulation glazing
(UW = 0.8 W/m²K); the space between the panes
was filled with argon gas. The total energy
transmittance of the glazing is equal to 0.55.
To ensure air tightness, a polythene sheet was
applied to the internal side of the walls; externally, a
roofing membrane was fixed to the walls, which was
hermetically bonded at the junctions. The air
tightness n50, which was determined in a blowerdoor test, amounts to 0.85 h-1.
Technical systems
In the 'Urban villa', a compact device with a heat
pump is charged with all the tasks of energy supply,
i. e. centralised balanced ventilation, DHW and
space heating. The essential components of the
device include: extract air heat pump, crossflow/
counterflow heat exchanger and DHW storage tank.
The exhaust air is extracted from the wet rooms to
be conveyed through a crossflow/ counterflow heat
exchanger, which transfers the heat gained in this
way to the intake air. A heat pump that was installed
in the extract airflow draws more heat from the
exhaust air and supplies it to the 200-litre DHW tank
and the heating system. As a heat pump is more
efficient at lower temperatures, the spaces of the
'Urban villa' were provided with a floor heating
system. The supply air will not be heated after
having passed the cross/ counterflow heat
exchanger. Before entering the evaporator, the
extract airflow can be mixed with outside air. In case
of very high heat demands for space heating or
domestic hot water, direct electrical supplementary
heating is possible.
www.tecalor.com
Financing
Energy performance
The final energy demand for heating and ventilation
amounts to 6.1 kWh/m²a; the demand for domestic
hot
water
is
6.6 kWh/m²a. These figures refer to electrical
energy. Accordingly, the primary energy demand
results to 18.3 kWh/m²a and to 19.9 kWh/m²a,
respectively. With a value of 38.2 kWh/m²a, the total
primary energy demand of the building is about
65 % below the permissible value of
110 kWh/m²a that is specified in the current German
regulations on energy conservation (EnEV).
Final
energy
[kWh/m²a]
Primary energy
[kWh/m²a]
Heating
6.1
18.3
Domestic
hot water
6.6
19.9
Total
12.7
38.2
Consumption
Planning tools
The energy demand for heating and preparation of
domestic hot water was computed in accordance
with the German calculation standards DIN 4108
part 6 and DIN 4701 part 10, as specified in the
German regulations on energy conservation
(EnEV).
Innovative products
Compact device for heating, ventilation, and
domestic water heating:
www.iea-shc.org
The evaluation of the energy concept was funded
by the German Federal Ministry of Economics and
Labour (BMWA), Berlin.
Project team
Manufacturer of the prefabricated building:
Haacke + Haacke GmbH + CO. KG,
Am Ohlhorstberge 3, D-29202 Celle
Architect:
Dr. Stauth, Braunschweig
Design evaluation and performance of the
monitoring programme:
Fraunhofer Institute for Building Physics (IBP),
Stuttgart.
Contact persons
-
Johann Reiß, Fraunhofer Institute for Building
Physics ([email protected])
Manufacturing Company
Haacke + Haacke GmbH + CO. KG
([email protected])
Literature
Reiss, Johann; Erhorn, Hans: Messtechnische
Validierung der 3-Liter-Haus-Stadtvilla in Celle [The
Celle 3-litre urban villa - Validation by
measurement]. IBP report (forthcoming).
www.ecbcs.org
Chignolo, Italy
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
The project
4-flat detached house with two 60 m2 units (one
bedroom) and two 120 m2 units (two bedrooms).
Building has two floors above ground, plus
basement with storage and parking and attic floor.
The house was built by a construction company
wishing to realize a demonstration building for lowenergy strategies and light Str/En construction with
a relatively traditional appearance.
Flats are wheelchair accessible thanks to a lift
linking basement and first floor levels.
Construction period was from February 2002 to
January 2003.
Objectives
The house was built with the aim of demonstrating
the feasibility of an extremely low energy
consumption level for winter and summer comfort in
the climate of Pianura Padana.
The house complies with the German “Passivhaus”
standard (15 kWh/m2 per year) for winter heating
and guarantees artificial summer cooling mostly
through renewable energy.
Moreover, light Structure / Envelope (Str/En)
technologies were used, in order to provide high
thermal and acoustical comfort, minimum energy for
transport and assembly (the whole building weighs
some 100 t) and possibility of final dismantling and
recycling of components. This is possible by
layering light and functionally specialized materials
on independent sub-structures.
Marketing strategy
The house was followed, during the construction
stage, by a research group of the Politecnico di
Milano – Dipartimento BEST, in particular on the
occasion of a PhD work. This is being followed
by a monitoring campaign that will control the
most critical parameters during one or more
years.
The experience was made public by articles on
specialized and generic reviews, books and
conferences (some of them international).
Building construction
The design strategy relies on heat conservation
in winter and protection from direct solar
radiation in summer. The envelope is hyperinsulated and made air-tight by a continuous
windproof layer in the walls, while thermal
bridges were minimized by the use of a
continuous, 6 cm thick thermal insulation layer
outside the perimeter walls.
As concerns summer, the windows are smaller
than is the norm in Central European countries
and they are all equipped with solar control
devices (aluminum Venetian blinds). Southfacing windows are protected from the sun by PV
panels that in winter do not prevent the sun from
entering the house.
U of opaque components (walls, roof) is lower
than 0.10 W/m2K;
U of windows is 1.5 W/m2K;
U of roof skylights is 0.8 W/m2K.
Double shell construction was used throughout to
ensure optimal thermal and acoustic separation
between exterior and interior.
Technical systems
All flats have mechanical ventilation for indoor air
quality reasons with heat recovery of 75% efficiency.
This ventilation air is post-heated, or post-cooled,
when the building is no more able to guarantee
spontaneously the indoor comfort conditions
(envelope as efficient climate filter). Post-treatment
of air is performed by a simple fan-coil unit per
apartment and floor, which is fed by hot or cold
water from an air-to-water heat pump.
The same heat pump produces domestic heat
water, thus eliminating completely fossil fuel burning
from the house – except for cooking.
Temperature and ventilation can be controlled
directly by the users, also remotely thanks to a
state-of-the-art domotic system.
In mild seasons, users can switch off the ventilation
and simply open windows (free-running mode).
A photovoltaic field installed on the south façade (36
m2) supplies electrical energy, covering some 40%
of the overall need over the year. Its production is
higher in summer, satisfying energy-demanding
cooling loads.
Energy performance
The heating consumption for the cold season is
lower than 15 kWh/m2 per year, that is some 80%
lower than current Italian regulations require.
Heating of space and ventilation air: 15 kWh/m²
(Air-to-water heat pump)
Domestic hot water: kWh/m²
(Air-to-water heat pump)
Fans and pumps: kWh/m²
Lighting and appliances: kWh/m²
Total calculated/monitored auxiliary energy demand:
kWh/m²
Total calculated/monitored energy demand: kWh/m²
(Please state if the figures are calculated or
monitored, or both)
Planning tools
Energy performance was checked against the
Passivhaus Institut tool Passivhaus
Projektierungspaket 2002 in order to classify the
house as such.
Costs and benefits
Capital costs for hyper-insulation and other energysaving strategies were in line with the mean costs of
Central European experience, but of course higher
in absolute value as the energy consumption
reduction is larger than in Germany (Italian current
consumption standard is far higher).
Innovative products
Str/En technologies
www.vanoncini.it
Building envelope
Window: www.faliselli.it; www.velux.it
Walls: www.knauf.it; www.sto.de; www.rockwool.it
Ventilation and cooling
Heat/cooling recovery unit: www.daikin.it
Controls
Solar and shade control:
Space heating and DHW
Heat pump: www.climaveneta.it
Electricity
Solar PV: www.siemens.it
www.iea-shc.org
Financing
None.
Project team
Design:
Brandolini Valdameri studio di architettura associato
Structures:
G. P. Imperadori
Technical installations:
Silvestri & Associati
Construction and detail design:
Vanoncini S.p.A.
Contact person
Pietro Antonio Vanoncini
([email protected])
Gabriele Masera ([email protected])
Literature and links
• G. Masera, Residenze e risparmio energetico, Il
Sole 24 Ore, Milan 2004 (italian).
• G. Masera, Passivhaus all’italiana, in “Costruire”
no. 241, june 2003, pages 34-39 (italian).
• M. Imperadori, G. Masera, Super-efficient energy
buildings, in Proceedings of the 31st IAHS World
Congress on Housing, Montreal 2003 (english).
• E. Zambelli, M. Imperadori, G. Masera, M.Lemma,
High energy-efficiency buildings, in Proceedings of
the 4th International Symposium on heating,
ventilation and air conditioning ISHVAC 2003,
Tsinghua University Press, Beijing 2003 (english).
• G. Masera, M. Imperadori, M. Silvestri, La
Passivhaus di Chignolo d’Isola: alto comfort, bassi
consumi, in Atti del 44° Convegno internazionale
AICARR 2004 “Impianti, edifici, città”, Milano 2004
(italian).
www.ecbcs.org
Chiryu, Japan
IEA – SHC Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
R=7.5
U=1.5
U=0.27
1F
2F
R=2.5
The project
The Okamoto Solar House is in a semi-urban town
of Chiryu, Japan. The town is close to Nagoya in the
central part of the Japanese main island (on the
pacific coast). This solar house is a single-family
house in a residential district. The project was
finished in February 2003.
The house has 3 bedrooms and an elder’s room with
kitchen and bathroom to make it possible to accept
homecare. The kitchen and dining room is often
used for cooking lessons and as a studio. The
garden is a spiritual, secluded shelter in this
crowded area.
Objectives
From the far past to the present, most Japanese
houses have not been heated whether whole house
or just during the winter - despite Japan having a
cold winter carried down from Siberia. This custom
has been the cause of various health and safety
problems, for example dewing, ticks, allergy, asthma,
heart attack, drowning in bathtub, etc.
Natural cooling, passive solar designs and active
solar techniques are applied to this house to provide
high quality of indoor climate through the year
through whole house, whole season heating with
same energy consumption compared to typical
present day Japanese homes, in which, only a few
rooms are heated or cooled as needed. Energy
demand for domestic hot water occupies more than
1/3 of Japanese home energy, so DHW should be
supplied by sun.
Marketing strategy
Seminars to educate the advantage of the solar
house for people interested in the new home
have been held more than 40 times a year
throughout Japan, featuring the hybrid solar
house “AMATELAS”. Some 200 home builders
are participating.
Building construction
Structure is by Japanese traditional “post and
beam” method with 105mm thick wall cavity. To
increase insulation thickness and minimize
wooden cold bridges, vertical and horizontal bars
are attached to make wall cavity thickness
140mm.
Exterior walls are insulated with cellulose
insulation, U-value 0.27 W/m2K.
Ceiling is 300mm cellulose insulated, R 7.5
m2KW (0.13 W/m2K).
Floor is slab-on grade, R 3.5 m2KW (0.29
W/m2K), solar heated heat-storage-floor is
insulated with 100mm foamed polystyrene, R 2.5
m2KW (0.4 W/m2K).
Windows are double glazed, low-emission coated,
argon filled, wood frame, total U-value of 1.5 w/
m2K. Ventilation with heat recovery is not applied
because of this rather mild climate but fresh air is
drawn via cool tube to reduce ventilation loss.
Solar Collecters
Shutter/reflector for
the Trombe wall
Technical systems
The house has a triangular plan with the widest wall
facing true south to maximize solar gain in winter.
The south roof has 45deg. tilt to provide maximum
winter insolation to the solar collectors. Airlock entry
and storages are arranged along north wall to be
buffers for the living space.
Passive and active hybrid solar system for floor
heating and DHW, named AMATELAS, is
developed for this house. A micro-processor is
central to AMATELAS and this system stores winter
solar heat in the floor for radiant floor heating,
makes hot water by excess solar heat, and activates
auxiliary boiler when necessary. This makes
AMATELAS the principal heating management
system to integrate auxiliary boiler with the solar
systems.
A 25m2 trombe wall, widest in Japan, occupies the
middle of the south wall, with a bi-fold R 2.5
(0.4W/m2K) insulated shutter and refractor, which is
automatically operated responding to the intensity of
the sun. The stainless steel surface of the shutter,
when it is folded, reflects the sunlight to increase
heat gain of the wall when it is needed, and when it
is not needed it is closed to reflect summer heat.
Disconnected from city water, well water is used for
domestic water demand, as well as space cooling
for some parts of the house, especially for the
bedrooms on tropical nights. Air conditioning is the
primary cooling system with the major demand in
the Japanese climate for dehumidification.
To provide good wind passages for either heated
nor cooled season, casement windows are used for
windows on east, north and west to provide both
small window area and free flowing air passages.
Energy performance
The heating energy demand is reduced to 26%
compared to a house with same floor plan and
insulated according to 1999 building code of Japan
(12% compared to 1992 building code). The houses
under ‘92 building code are not heated whole house
or whole winter, so this comparison makes no sense.
Total energy demand is reduced to 59% (40%
compared to ‘92 building code)
Heating of space and ventilation air:
Domestic hot water:
12.1 kWh/m²
8.9 kWh/m²
(Energy source: Kerosene,
monitored total
22.2 kWh/m²)
Cooling of space and ventilation air: 10.8 kWh/m²
(Energy source: Electricity, COP 3.0,
monitored
4.5 kWh/m²)
Fans and pumps:
2.2 kWh/m²
Lights and appliances:
36.9 kWh/m²
(Energy source: Electricity,
monitored total
40.9 kWh/m²)
Total calculated energy demand:
70.9 kWh/m²
(Total monitored
69.6 kWh/m²)
•Degree Day (20-12) for heating : 1940
•Degree Day (18-18) for heating: 1840
•Degree Day (24-24) for cooling: -199
Planning tools
Energy demand simulation by SMASH and
EESLISM.
Costs and benefits
The cost of the house is approximately 340,000
Euro, including costs for solar systems and other
energy saving techniques. This is estimated 8-10%
more expensive than a same house assumed to be
built according to 1999 Japanese building code.
Project team
Architect: Okamoto Yasuo (Chiryu Heater)
Contractor solar: Chiryu Heater
Builder: Kyowa Kensetsu
Contact person
Okamoto Yasuo(ChiryuHeater)
[email protected]
Anyone in Chiryu Heater
[email protected]
Innovative products
Space heating and DHW
Hybrid solar house system “AMATELAS”:
http://www.chiryuheater.jp
Envelope
Cellulose insulation: http://www.chiryuheater.jp
Windows: http://www.andersenwindows.com
www.iea-shc.org
www.ecbcs.org
A ZERO ENERGY HOUSE
(a low energy house with PV
system)in
Kanagawa, Japan
IEA – SHC Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
GUEST
ROOM
1F PLAN
ATELIER
LIVING
ROOM
Section
Insulation Spec.
WALL
PALC80mm + GW125mm
FLOOR
GW100mm
ROOF
GW150mm
WINDOW
+
AL+Plastic sash Triple glazed
2F PLAN
ROOM1
Roof integrated PV system
ROOM2
The project
This house was built at Kanagawa pref. (near
Tokyo) as a zero energy house. The building is a
single-family house private development. The Zero
Energy House (named Hybrid-Z), was developed
through technology and the experience accumulated
by Misawa Home, who are a housing developer that
specializes in this kind of development.
Objectives - Goals
The main goal for the home was to create a
comfortable living space with a low energy demand.
It is impossible to enjoy comfortable indoor life
through all seasons due to Japanese climate
condition without some technological intervention.
Misawa Homes to ensure that a development has a
energy demand close to zero by the adoption of
energy saving technology and reduction of energy
consumption. We define this house as "Zero Energy
House". The home aims to not be reliant on external
sources of energy from, for example, gas and oil.
This means supplying energy required for living by
renewable sources of energy such as photovoltaic
power generating system.
ROOM3
Building Spec.
Total Floor area :228.56 ㎡
K values : Wall 0.38 W/Km2
U
Roof 0.48 W/Km2
Floor1.00W/Km2
Window 2.55 W/Km2
Total equivalent leakage area : 891 cm2
3F PLAN
Heat loss coefficient : 441.1W/K
The photovoltaic power generating system can
produce the energy equivalent to consumption
energy. The photovoltaic power generating system
should not be the only solution, we should also seek
to reduce our consumption. Improvement of thermal
insulation performance and the design of a home
that reduces energy consumption of the air
conditioning is important. Using high efficiency
products for air conditioning, water supply and
kitchen reduces consumption of energy in this home
also. It is necessary, however, that this technology is
at a reasonable price for wide spread use. Therefore
an affordable price is a main goal for the project.
After considering all the factors, "Zero Energy
House" is designed and built by Misawa Home.
Building construction
The outer wall covering of this house, Hybrid Z,
which is a laminated wall of 234mm thick based on
new ceramics (PALC) of 80mm thick, wraps around
the whole house. Windows, which have great
thermal loss, employ triple glass sash, which
improves thermal insulation and air-tightness of
housing itself. Realizing a house that is naturally
kept cool in summer and warm in winter positively
serves to suppress excessive energy consumption
in air conditioning.
Energy Balance (Annual)
Energy Comsumption(night-time)
10,000
1,500
8,000
1,200
1,500PV Generation
180%
Zero-Energy ratio
180%
160%
600
140%
600
140%
300
120%
[kWh]
[kWh]
300
0
120%
0J an
100%
Fe b
M ar
A pr
M ay
Ju n
Jul
Aug
Se p
Oc t
Nov
Dec
-300
80%
-4,000
-600
60%
-6,000
-900
40%
-8,000
-1,200
20%
-10,000
-1,500
0%
-300
-600
-900
-1,200
-1,500
Jan
-12,000
Feb
Mar
Apr
May
Jun
PV Generation
Energy Comsumption(night-time)
Cost Balance (Annual)
25,000
250,000
25,000
200,000
Jul
Aug
Sep
Oct
0
-50,000
-100,000
Buying Electricity
20%
Dec
225%
20,000
Zero-Energy ratio
225%
200%
200%
175%
15,000
175%
10,000
150%
125%
0
125%
100%
-5,000
100%
75%
-5,000
-10,000
75%
50%
-10,000
-15,000
50%
25%
-20,000
25%
0%
[Yen]
5,000
5,000
0
J an
Fe b
M ar
A pr
M ay
Ju n
Ju l
Aug
Se p
Oc t
Nov
Dec
-15,000
-150,000
40%
Cost Balance
20,000
[Yen]
[Yen ]
50,000
60%
Energy Comsumption(day-time)
Zero-Energy ratio
10,000
100,000
80%
Cost Balance
Selling Electricity
100%
0%
Nov
15,000
150,000
200%
160%
900
2,000
[kWh]
200%
900
4,000
-2,000
Energy Balabce
Energy Balance
1,200
6,000
0
Energy Comsumption(day-time)
-20,000
Jan
Feb
Mar
Apr
Buying Electricity
Technical systems
The PV system on the roof of this house has a
11.3kW value over all ( east side:5.2kW, west
side :6.1kW). This is made of reinforced glass
surface and crystallized silicon has a high durability,
and never causes harmful substance or noise in
generating power. When the electricity generated
by photovoltaic power generation system is in
excess of energy consumed in the house, surplus
electricity is automatically sold to power companies.
It is the very ideal system in terms of environmental
preservation as well as for enriched living. Energysaving technology such as this is the base for
realizing zero-energy homes,. Further energy-saving
technology, for example in the air conditioning, is
provided by a heat pump system and the COP is
over 3.0, in hot water supply, the hot-water is heated
during the night to benefit from lower electricity
costsand reduces power consumption at the daytime at peak-cost. In kitchens, IH portable cooking
heater is adopted with thermal efficiency as high as
90% and less waste heat, contributing to
improvement of efficiency of equipment.
May
Jun
Jul
Aug
Selling Electricity
Sep
Oct
Nov
150%
Dec
0%
Zero-Energy ratio
Energy performance
Actual data that makes reference to the energy
performance of this house are shown in the above
figures. The energy consumption of this house is
8,500kWh/year whereas the PV generation is
8,000kWh/year. The PV generation, therefore,
covers 94% of the consumption.
(Electricity)
Heating
1,600kWh
Cooling
1,200kWh
Domestic hot water
2,100kWh
Lighting and appliances
4,000kWh
Total
8,900kWh
Costs
This house was subsidized from New Energy
Foundation in accordance with the subsidy program
for residential PV system. The subsidy ratio of this
program is 1/3 in the total installation cost. In result,
the total additional cost compared to a reference
standard house is 7 million yen, and the saving
running cost is about 300,000yen per year.
Planning tools for LCA, energy performance, solar
energy design and more
Air conditioning load calculation software “SMASH”
Parametric analysis method (PV generation)
Other information
H Ida,I Ohta(Misawa Homes Institute of R&D co.,Ltd);
“Zero Energy Home” ,ECO DESIGN 2001 in Tokyo
Marketing strategy
Hybrid-Z, which satisfies basic condition of “Photovoltaic
power generation system all over the roof” “High thermal
insulation” and “Equipment with high efficiency”, was
authorized as the first zero-energy house by the Institute
for Building Environment and Energy Conservation
(IBEC).
Direct current electricity generated by
the solar power generation sysytem
is converted to alternating current by
the inverter.
Equipments in the house are all highperformance ones and can utilize the
solar power.
www.iea.shc.org
www.ecbcs.org
KankyoKobo,
Sunny Eco-House
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
Floor plans (Total floor area:150.35m2)
The project “Kankyo Kobo”
-Single family house with two stories
-Date of completion: April 1st 2000
-Total floor area: 117.90–167.47m2
-Private built house and Ready-built house
-Number of houses sold:
(Apr 2000 through Sep 2002)
Objectives
Building construction
“Protect the environmentモ is now vital to every
human being on Earth. Daiwa House, as a
housing company, proposes a solution to the
matter.
Industrialized house
Kankyo Kobo is a prefabricated house, a
structure with a high and stable quality formed
with steel frames and proof stress panels. All
the panel frames, exterior wall materials, heat
insulating materials, and window sash frames
are preset in the factory.
Painting exterior walls is also carried out in the
factory in order to avoid the possible air
pollution to the surroundings.
The air tightness is improved by binding panels
with highly efficient bolts and by patching
sheets and taping scrupulously.
Light gauge steel is used for the frames,
ceramics for the exterior walls, highly efficient
glass wool for heat insulating materials.
In cold districts, a greater amount of insulating
materials are utilized to improve the efficacy.
Longer eaves prevent the fierce sunlight of
summer and reduce the energy for airconditioning. The rays of sunlight in winter can
shine into the rooms and heighten the
effectiveness of heating.
Kankyo Kobo satisfies “the Next Generation
Standards” in every district of Japan.
Improving energy efficiency, utilizing natural
energy, and making the most use of natural
resources was our policy when we developed
our Eco-house, Kankyo Kobo.
1. Improving energy efficiency
Kankyo Kobo, with highly efficient performance
for insulation and air tightness, satisfies the
Japanese
Housing
Energy
Efficiency
Standards established by the Ministry of Land,
Infrastructure and Transport, so-called メNext
Generation Standards モ in force since April
2002.
It has potential to reduce the CO2 emission by
58.6% compared to the houses built in
accordance with the Housing Loan Corporation
standards, one of the requirements for the loan.
2. Utilizing the natural energy.
To utilize natural energy effectively, Kankyo
Kobo is equipped with solar cell and solar
collector.
3. Making the most use of natural resources
The water reclaim system is adopted to reduce
the use of clean water. The reclaimed
graywater is used for toilet flushing and garden
sprinklers.
The kitchen unit is designed to facilitate the
classification and storage of the recyclable
items.
Although ecology conscious housing is usually
expensive, we developed this prefabricated
house, Kankyo Kobo, and realized and
affordably priced Eco-house.
In addition, a drastic reduction of volatile
organic compounds (VOCs) has been achieved.
With its barrier free design, Kankyo Kobo
supports the health and a comfortable life.
System and material spec
District III
Districts IV & V
Roof/Ceiling
Exterior walls
General
Flooring
Material/System
K-Value
Material/System
K-Value
Blow-forming cellulosic fiber(25kg type), t=160
0.24
Blow-forming cellulosic fiber(25kg type, t=160)
0.24
Blow-forming cellulosic fiber(25kg type, t=200)
0.19
High efficiency glass wall (16kg type), t=72
0.59
High efficiency glass wall (16kg type), t=100
0.45
High efficiency glass wall (16kg type), t=100
0.45
1.00
Hard polyurethane foam t=20
0.88
Hard polyurethane foam t=20
0.88
0.51
Polystyrene foam sheet (B3),t=62
0.51
Polystyrene foam sheet (B3),t=62
Polystyrene foam sheet (B3),t=45
Tatami
Unit bath
Window
Aperture
K-Value
Between floors Hard polyurethane foam t=20
General
District II
Material/System
0.52
Polystyrene foam sheet (B3),t=45
0.52
Polystyrene foam sheet (B3),t=62
0.51
Hard polyurethane foam t=80
0.34
Polystyrene foam sheet (B3),t=45
0.52
Hard polyurethane foam t=80
0.30
Hard polyurethane foam t=10
1.46
Hard polyurethane foam t=10
1.46
Hard polyurethane foam t=10
1.46
High adiathermic air-tight sash
2.91
High adiathermic air-tight sash
2.91
Resin sash
2.33
High adiathermic double-glazing glass (A12)
High adiathermic double-glazing glass (A12)
High adiathermic double-glazing glass (A12)
Front hall door adiabatic door
2.33
adiabatic door
2.33
adiabatic door
2.33
Back door
2.91
adiabatic door
2.91
adiabatic door
2.33
adiabatic door
Ventilating system
New-VAC system
Heating system
Connecting sleeves & outlet for air conditioner in each
Connecting sleeves & outlet for air conditioner in each room Central hot water heating
room
Air tight works
Patching sheets, taping & etc.
Insulation efficiency (Q-value)
New-VAC system
PAC system
Patching sheets, taping & etc.
2.37
Patching sheets, taping, airtight outlet & etc.
2.21
Polystyrene foam sheet: 1.74
Hard polyurethane foam: 1.68
heat loss coefficient: W/m2K
(Next Generation Standards)
Insolation shielding efficiency (μ)
(Next Generation Standards)
Air tightness efficiency:
C-value cm2/m2
(Next Generation Standards)
(2.70)
(2.40)
(1.90)
0.07 and below
0.07 and below
0.08 and below
(0.07 and below)
(0.07 and below)
(0.08 and below)
5.00
5.00
2.00
(5.00 and below)
(5.00 and below)
(2.00 and below)
Disctrict II: Cold districts, District III: Coldish districts, Districts IV & V: Temperate districts
Technical systems
-Energy saving devices
-Ventilation
Variable Air Control (VAC) System:
Standard model (III IV V on the list above)
Ecology conscious ventilation system with the
convergence control. Inspiration grill which
opens and shuts censoring the atmospheric
temperature change adjusts the air intake.
Photocatalytic Air Cleaning (PAC) System:
Cold district model (II)
In cold districts, PAC is introduced. It heats the
outside air up to the indoor temperature before
intaking. The system holds down the heat loss.
Common device
Motor operated air-cleaning louver is installed
in the monitor roof.
Window glass
There are the three types of glass, heat-sealed
high adiathermic double glazing glass, high
adiathermic double glazing glass and double
glazing glass. The one best suited to the
climate of the location and the direction of the
windows will be chosen.
Window sash
Resin framed sashes for the cold district (II),
and High adiathermic sashes for the other
districts (III, IV, V)
Doors Adiabatic doors
High adiathermic doors (k=2.33)
Lighting apparatus
Inverter lighting is used in corridors to reduce
the electricity.
Automatic lighting system is introduced on the
porch. The light is switched on by a censor that
perceives a human approaching.
Energy saving performance
Insulating material
Comparison of heat loss coefficient
Energy performances
- Solar energy generation
PV cells are a hybrid type of monocrystal and
amorphous. Conversion efficiency is favorable
of 17.3%, and decrease of power generation by
heat is suppressed. Loading capacity is 3.00kw.
Exterior appearance is designed to go well with
the plain roof tiles.
At night, when the solar power cannot be
obtained, electricity is bought from the power
company. Surplus energy can be sold to the
company.
With the system of 3.00kw, annual production
of electricity is estimated at 3,382kw. At the
same time, the average electricity consumption
of a general household is 6,336kw a year. 53%
of consumption will be generated domestically.
(Simulation model: Average family of 4, Total
floor space of 150 m2, in Osaka)
An indoor monitor shows the power generation
to raise the residentsユ awareness.
-Solar collector
Hot water from the solar collector with
controlled circulation system is potable and can
be supplied to 3 to 4 feeders, contrary to the
natural circulation system.
Solar
utilization
reduces
the
annual
consumption of gas by 54%.
Solar collector and hot water supply
Annual average electric power consumption
and generation expectancy
Recycling facilities
Recycling of graywater
Marketing strategy
-Recycling of graywater
Rainfall and discharged water from the bath
tub are decontaminated and utilized for toilet
flushing and water spray for plants in the
garden or for car washing. This recycling of
water can reduce the use of clean water by
200 liters per day.
Costs ¥ 25,220,000 (150.35 m2) ¥ 167,700 /m2
Without solar system ¥ 21,268,000 (150.35 m2) ¥ 141,400 /m2
Kankyo Kobo is not an idealized prototype of a
solar house, but an industrialized house with an
affordable price. It supports the residents ユ
healthy and comfortable eco-life with solar energy
utilization, graywater recycling, and garbage
recycling and with the devices to make life easier.
Housing with energy saving efficiency or a solar
system can be the object of an extra-loan from
the Housing Loan Corporation. In addition, the
New Energy Foundation supplies the subsidy to
the energy generated by solar power, ¥100,000
per kw with the limit of 10kw (April 2002 through
March 2003).
These advantages are a part of our marketing
strategy.
Other information
Daiwa House Industry Co., Ltd., Japan
3-5, 3-chome,Umeda,Kita-ku,Osaka 530-8241 JAPAN
Phone:(06)6342-1402 Fax:(06)6342-1591
http://www.daiwahouse.co.jp/
www.iea.shc.org
www.ecbcs.org
A low energy house with
(1)all heat exchange type central air
conditioning ventilation systems,
(2)passive solar,
(3)the photovoltaic system.
Kyoto, Japan
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
Rest Room
Rest Room
Strage
Kitchen
Room1
Living
VOID
Room2
Dining
1F
PLAN
South side elevation
The project
This residence is built in Kyoto. Kyoto is an area
where it becomes 35 degrees C of maximum
temperature in a summer, and thelowest
temperature becomes 0 degree C in winter. It is a
residential section and is the site where there is no
high building in the circumference, and on the south
and the west sides serve as a road. In order to
employ the condition efficiently effectively, "the
passive solar system of a direct gain system" is
adopted.
The number of these residences is two and the floor
of living and a dining room is a thermal storage floor.
the upper part of living serves as a big well Since
the large opening is taken in the well upper part,
solar heat can fully be taken in to the back of living
in winter. Moreover, as for the second floor portion,
the device to which the first floor portion does not
put in direct solar heat indoors in a summer by
planting of the yard is given by eaves. And reflection
of the solar heat to the first floor is suppressed by
planting many plants in the yard on the south. About
the western opening, the influence of the solar heat
from the west side of a summer is suppressed by
making a opening small as much as possible.
2F
PLAN
West side elevation
Objectives - Goals
By consuming much energy, our old life has
acquired convenience. However, the increasing
energy consumption has given the serious damage
to earth environment. We are asked selecting the
compact life style, which does not apply load to
environment. It is using energy for it without futility
and maintaining convenience with the least
possible energy. The residence introduced here is
the example which adopted all heat exchange type
central air conditioning ventilation systems, passive
solar, and the photovoltaic system, and just
mitigated the damage to earth environment.
Building construction
This residence is two-by-four structure. Two-by-four
structure is the method of construction which was
excellent in heat insulation nature and air-tightness
from the first.
However,the heat insulation performance is raised
as follows.
In order to acquire the thermal storage effect of
solar heat effectively, heat insulation and the
airtight performance of a residence are becoming
important. In the heat loss coefficient [Q value] of
this residence, 1.6W/ m2K and the equivalent
leakage area [C value] serve as 3cm2/m2.
Solar Energy
Solar Energy
Solar Energy
Solar Energy
High heat insulation
High heat insulation
specitication
specitication
24-hour ventilation system
24-hour ventilation system
Thermal stage floor
Thermal stage floor
Winter
Technical systems
In winter, a passive solar system accumulates the solar
heat which goes indoors at daytime in the thermal storage
floor of concrete. A thermal storage floor heats a floor with
the heat slowly at night. Work like a natural floor heater is
carried out. Conversely, in a summer, direct solar heat is
made for eaves not to enter indoors.
An indoor temperature rise is suppressed by doing so.
There are few energy losses and they fill the inside of a
residence with adopting all heat exchange type central air
conditioning ventilation systems with clean air. In this
residence, since it is considering as the system of air
conditioning one apparatus, comfortable nature with few
differences of temperature in a residence has been
realized. Moreover, photovoltaic system 4.53kW is
installed in this residence. That is, the solar blessing will
have been acquired from passivity and active both sides.
This residence is an all electrification residence which
adopted the electric induction heater and the electric warm
water machine, and provides all energies electrically.
Summer
Energy performance
(1)Winter temperature measurement result
The living into which, as for winter, solar heat goes is
over 20 degrees C daytime. There is no necessity of
heating most night. The Japanese-style room is 18
degrees C - 20 degrees C under the influence of living
daytime. It is not heated like [ a Japanese-style room ]
living most night. The main bedroom is made into the
setting temperature of 15 degrees C. Although heating is
hardly used through one day, the extreme temperature
fall is not produced.
(2)Summer temperature measurement result
Since solar heat is covered well, there is no necessity of
making air conditioning temperature low extremely. The
temperature of each room is 25 degrees C - about 28
degrees C.
(3)The amount of photovoltaic system power generation
Since on the south is opened wide and sunlight can fully
be obtained, about 400kW has been generated
constantly every month. 3690kW of about about 90000
yen is generated in the sum total in April - December.
The abbreviation half is provided in May - September
with little electric use by power generation of a
photovoltaic system.
(℃)
(℃)
40
26
Open Air
24
35
Living
22
20
30
18
25
16
14
Japanese-style
Room
20
12
Room
10
15
Room1
Living
8
Room1
10
6
4
5
2
0
0
12
21/1
1/21
21/1
0
12
1/22
22/1
0
12
1/23
23/1
0
12
1/24
24/1
0
12
0
1/25
25/1
12
0
12
0
1/27
27/1
1/26
26/1
12
0
1/28
28/1
12
0
29/1
1/29
12
1/30
30/1
0
0
12
0
8/5
5/8
12
0
12
8/6
6/8
Temperature of a winter
8/7
7/8
12
8/8
0
12
0
8/9
9/8
12
8/10
10/8
0
12
8/11
11/8
0
12
8/12
12/8
0
12
8/13
13/8
0
12
8/14
14/8
Temperature of a summer
発電量
・The amount
電力使用量
・The amount
2000
太陽光発電システム発電量
2000
(kWh)
0
1800
1800
1600
1600
1400
1400
1200
1200
1000
1000
800
800
600
600
400
400
200
of power generation
of used electric power
200
0
0
4月
Apr.
5月
May
6月
Jun.
7月
July
8月
Aug.
9月
Sept.
10月
Oct.
11月
Nov.
12月
Dec.
The amount of photovoltaic system power generation
Costs
The expense, which starts when these systems are
carried, is as follows. It costs 1,800,000 yen to carry
a whole building air-conditioning ventilation system.
It costs 3,300,000 yen to carry photovoltaic. It costs
450,000 yen to carry a passive solar system. It costs
250,000 yen with the difference that changes a gas
hot-water supply machine and a gas range into
electrical machinery. Sum total expense changes to
5,800,000 yen.
Planning tools for LCA, energy performance,
solar energy design and more
Special tools and analyses done for the building.
Marketing strategy
By the ability of a resident to use the subsidy
obtained by carrying these system , we are raising
the rate of system loading.
The subsidy of the "residence and building efficient
energy system introduction promotion base
enterprise" of NEDO (New Energy and Industrial
Technology Development Organization) is
received for a passive solar system, a central air
conditioning ventilation system, an IH cooking
heater, and housing heat insulation strengthening.
A subsidy frame is 1/3 of the expense concerning
the object system, and changes to about
1,200,000 yen in this residence.
Other information
These systems are studied at the MITSUBISHI Estate home – Comfortable air research institute.
Common text about Task 28
www.iea-shc.org
www.ecbcs.org
Okayama, Japan
IEA – SHC Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
U=0.22
Roof top bath
U=1.60
U=0.45
U=0.32
2F
1F
The project
This single-family house is in the suburb of
Okayama, on the beautiful bank of Asahi River,
overlooking clear water flow and reedy marsh. The
project finished in February 2003.
Total floor area is 233m2.
Marketing strategy
The owners often open their house for people
interested in the new home, to educate and to
highlight the importance of heating the whole
house through the winter, of which most
Japanese homes have not benefited from in the
past.
Objectives
Low energy demand, with good and stabilized
indoor climate, is the main target of this project.
A solar water heater is used for DHW demand
including hot water for a roof-top bath to enjoy a
Japanese dream to take bath under the starlight,
looking over the river and city lights far beyond.
Building construction
The building is constructed by reinforced
concrete so as to benefit from thermal mass
inside the insulation envelope.
Windows : Dual pane, low emission coated,
argon gas filled, wood framed. Overall U-value is
1.64 w/m2K
Wall: Foamed polystyrene (50mm, R 1.79
m2K/w) over 150mm concrete. U-value 0.45.
Floor: Foamed polystyrene (75mm, R 2.68
m2K/w) over 200mm concrete. U-value 0.32.
Roof: Foamed polystyrene (115mm, R 4.11
m2K/w) over 200mm concrete. U-value 0.22.
summer
winter
Technical systems
South facing window area is optimized by
calculation, to maximize winter solar gain and
minimize heat loss.
Eaves are carefully designed considering solar
position for each season, as illustrated above.
Concrete structure inside the insulation envelope is,
coated with plaster, naked and exposed to the room
temperature to maximize the heat absorption in the
daytime.
8 m2 of solar collectors are installed on the roof for
solar water heating with 370 liter storage tank.
Auxiliary heating is by radiant floor heating installed
in the 2nd and 3rd floor and in the roof top bathroom
as well.
Energy performance
The auxiliary heat demand is calculated for 3 cases.
A: This demonstration building.
B: Building with same plan but has insulation
according to 1999 Japanese building code.
C: Building with same plan but has insulation
according to 1992 Japanese building code.
The heating energy demand:
A: 27.4 kW/m2, while B 63.4 kW/m2
The DHW energy demand:
A: 6.4 kW/m2, while B 22.4 kW/m2
The cooling energy demand:
A: 17.5 kW/m2, while B 17.1 kW/m2
Pumps and fans
A: 2.2 kW/m2, while B 5.3 kW/m2
Lights and appliances
A: 36.8 kW/m2, while B 36.8 kW/m2
Total energy demand:
A: 90.3 kW/m2, while B 145.0 kW/m2
The heating energy demand and the total energy
demand for C is calculated to be 134.6 kW/m2 and
203.2 kW/m2, but buildings according to 1992
building code is not heated whole house, so the
comparison has no reality at all.
Degree Day(20-12) for heating : 1866
Degree Day(18-18) for heating: 1822
Degree Day(24-24) for cooling: -240
Planning tools
Energy performance calculation tool
SMASH
Costs and benefits
The extra costs for energy concept, taking into
account reduced costs for heating and solar hot
water system, is 13,000 EURO, compared to the
same building with 1999 building code and without
solar water heater.
Innovative products
Solar water heater: http://www.chiryuheater.jp/
www.iea-shc.org
Financing
The subsidy of the New Energy and Industrial
Technology Development Organization(NEDO)
partly assisted.
Project team
Architect: Uno Tdahide
Solar water heater: Chiryu Heater
Builder: Okayama Komuten co.,ltd.
Contact person
[email protected]
www.ecbcs.org
A Sustainable Solar House
with OM Solar System in
Hamamatsu, Japan
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
www.iea.shc.org
Sustainable Solar Housing
www.ecbcs.org
The project
This house was built at Hamamatsu of Shizuoka Pref. in
the fall of 2002. It is a prefabricated house ( named Volks
Haus -ProjectA ) equipped with the OM Solar system.
Volks Haus are a concept and an aim that is completely
different from those of prefabricated houses offered by
Japan’s home manufacturers. The fundamental idea of
Volks Haus is to use a wide space as effectively as
possible before dividing it into rooms, hall, etc. This is
different from building houses from a finished floor plan.
The plywood used for structure is left in its original state
to form the inner walls. The ceilings and the floor of the
second floor are also left in the original state of laminated
wood and plywood. This method can be called an
exposed wood method, from its resemblance to the
exposed concrete method.
The body of Volks Haus is built of prefabricated posts
and beams that are joined by metal joints. Insulated
panels are fitted in between posts. These panel serve as
braces. Because it uses metal joints instead of traditional
joints, the house can be put together without
conventional skill. The project has been applied to more
than 3,000 homes and the OM Solar system has been
used in more than 20,000 homes.
Southern view of the house
Lavatory
Closet
Design concept of the house
Kitchen
1000kcal/day 100mm/month
m/s
The house was ordered by a three-person family. The
husband was a salary man in age of 35 and his child was
a three-month-old boy. Since married, the couple was
living in an apartment. After their son was born, they
hoped to build a theirs own home with their savings.
The house was aimed to be designed based on the
following points.
• Employ the OM Solar system to create a comfortable
living space by using the solar heat.
• Externals of the building are well-matched with the
wooden deck and planting.
•Built of wood and internal walls are finished with plaster.
•The kitchen is the center of the home and Islandshaped.
•The living room is integrated with the deck.
Deck
50
100
5
40
80
4
30
60
3
20
40
2
10
20
1
0
0
0
-10C % )
(゚
Feb
Mar
Apr
May
Jun
Daily roof radiation(kcal/㎡)
Daily horizontal radiation(kcal/ ㎡)
Monthly mean air temperature( ゚ C)
Monthly mean relative humidity(%)
Jul
Aug
Sep
Oct
Nov
1F Plan
Parking
6
Jan
Living/Dining Room
Room with
tatami (mat)
Closet
Child Room
Bed Room
Open
Dec
Monthly precipitation(mm)
Daily maximum air temperature( ゚ C)
Daily minimum air temperature(゚ C)
Monthly mean wind speed(m/s)
Veranda
2F Plan
Annual meteorological data for Hamamatsu
Climatic conditions of the location (Hamamatsu)
Hamamatsu is located in the central middle part of Japan (N34゚42’, L137゚43 ’), where heating is required for five months from
November to April. Because the daily sum of horizontal solar radiation exceeds 2000kcal/m2day in these months, the effect of the OM
Solar heating can be expected in the heating-required months.
Solar system Specification
Glass-covered heat-collector: 16m 2
Metals heat collector: 11m2
Under-floor storage:64m2
Volume of fresh air supply:
600m3 /h (during heating / cooling)
Hot water tank: 300liter
Building Specification
Total floor area: 116m2
K values: Roof 0.31W/Km 2
Wall 0.59W/Km 2
Floor 1.85W/Km2
Window 3.49W/Km2
Total equivalent leakage area: 2.4cm2 /m 2
Heat loss coefficient: 2.71W/Km2
Section
Insulation Specification
Roof
Polystyrene foam 98mm
Wall
Polystyrene foam 50mm
Floor
Polystyrene foam 25mm
Window
Wooden sash, Double glazed
Technical systems
The OM Solar system operates on the principle of
taking solar-heated air collected under the surface of
a building's roof and channeling this hot air, via an
interior vertical duct, down beneath the ground floor to
a heat-storing concrete slab. This concrete slab
warms the ground floor and releases hot air through
floor vents for distribution throughout the building's
interior spaces. Auxiliary devices come into operation
for hot water supply and for backup heating on
overcast or very cold days.
When external air exceeds a certain temperature, hot
air collected under the roof's surface is expelled
through an exhaust duct located directly under the
roof without being circulated through the interior
spaces.
The underfloor concrete slab, which as pure thermal
The OM Solar system on a sunny winter day
mass saves heat in winter for release at night and on
cloudy days, also serves to cool the
house in summer by releasing, during the high-temperature daytime hours, the coolness it accumulates during the lowtemperature nighttime hours.
Heat balance in an OM Solar house comprises three factors: heat collection, heat storage and insulation/air- tightness.
Insulation and air-tightness are especially critical factors in providing energy-efficient and comfortable living conditions
during winter, yet completely sealed structures are to be avoided because of the need for regular ventilation. A key
feature of the OM Solar system is that it provides home occupants with continuous fresh air circulation.
Planning tools for solar energy design, energy and thermal performance
OM computer simulation software “SunsonsV5” is used to design an OM Solar house before construction and the
software was authorized as an heating/cooling load calculation software by the Institute for Building Environment and
Energy Conservation (IBEC), Japan.
Thermal performance of the house
As shown in the top of the next page, on a clod day (Jan. 23 ) an outdoor morning temperature of -2℃ gradually rose to a
high of 8.5℃. The daytime temperature of the OM Solar heating air reached 60℃ or so. As a result, indoor temperature
was maintained at 15℃ in the morning and rose to a high temperature of 23℃. On a cloudy day as Jan. 21, although the
solar heat was not obtained, the room temperature was kept above 17℃. Note that this data was recorded in the coldest
month for the year 2004.
On the other hand, the data collected in summer is also indicated in the middle of the next page. The difference between
daytime and nighttime outdoor temperatures was more than 12℃. Under these conditions, the most effective way to
maintain a comfortable interior temperature is to shut out external heat during the day by keeping the windows closed,
and then to open the windows at night and/or bring external cool air into the interior through OM Solar system operation.
On a hot day as Aug. 24, daytime outdoor temperature exceeded 35℃, while nighttime temperature dropped to 24℃.
The room temperature was maintained at between 29℃ to 32℃ during the day long without resorting to an air
conditioner.
100
Temperature(℃ ) Humidity(%)
90
80
70
60
50
40
30
20
10
0
-10
External humidity
Humidity of family room
Roof duct temperature
Temperature of family room
External temperature
-20
1/17
1/18
1/19
1/20
1/21
1/22
1/23
1/24
1/25
1/26
1/27
Monitored data for a 11-day period in winter 2004
100
Temperature(℃ ) Humidity(%)
90
80
70
60
50
40
30
20
External humidity
Humidity of family room
Temperature of family room
External temperature
10
8/18
8/19
8/20
8/21
8/22
8/23
8/24
8/25
8/26
8/27
8/28
Monitored data for a 11-day period in summer 2003
Energy performance
The calculated heating load of the house for a year is given in the following table. It shows that 59% of the annual heating energy
can be supplied by the solar heat (OM Solar system). An actual data of energy performance for a year is also listed in the following
table. As an auxiliary heating system, a kerosene stove was used in this house. The gas was not used. The kerosene consumption
for heating energy during a winter-period( Nov. 2002 to Mar. 2003) is about 548L that is equivalent to 3651Mcal(31.5Mcal/m2).
Heating load calculated OM computer simulation software “SunsonsV5”
OM Heating(Mcal)
Auxilairy Heating(Mcal)
Nov.
419
0
Dec.
543
387
Jan.
513
930
Feb.
474
731
Mar.
739
153
Apr.
505
19
Year
3193
2220
Ratio
59%
41%
Energy consumption recorded for a year from Nov. 2002 to Oct. 2003
Nov. Dec. Jan. Feb. Mar.
Kerosene(L) 40 133 140 156 79
Electricity(kWh) 477 457 612 611 604
24
23
23
20
22
Water(m 3)
Apr. May
0
0
577 475
23
24
Jun.
0
539
25
Jul.
0
552
25
Aug. Sep. Oct.
0
0
0
659 675 526
27
29
29
Year
548
6764
294
OM Solar Association
4601 Murakushi-cho, Hamamatsu, Shizuoka Prefecture , 431-1207 JAPAN
Phone:(053)-488-1700 FAX:(053)-488-1701
http://www.omsolar.net/
Example of a Prefabricated House
with Solar Power Generation System
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
The project and the Objectives - Goals
The number of households using a solar power generation system in Japan has rapidly increased in the last three to four
years. This trend is due to the expanded coverage of the solar power subsidy, more widespread buying by electric power
companies of electricity generated by each household which is surplus to needs (hereafter referred to as “electricity
sales”), and mainly due to increased consumer awareness about the importance of generating clean energy in their
homes.
Increase in Number of Houses with Solar Power Generation System
(Number of Houses)
35000
30000
25000
20000
15000
10000
5000
0
1994
1995
1996
1997
1998
1999
2000
2001
Based on survey of New Energy Foundation
The solar power system consists mainly of a solar cell
module and a power conditioner.Since the solar cell
module used here doubles as the roofing material, it
blends well with the entire building design as well as the
street appearance. Furthermore, as no additional roofing
material is required, the cost is lower in comparison with
conventional solar cells. The direct current generated by
the solar cell module built into the roof flows through the
power conditioner, and after being converted to
alternating current as used in general households, is
distributed from the panel board to each electric appliance
in the house. Since the system operates automatically (it
starts operating when it receives sunlight and stops when
there is no sunlight), no human intervention is required.
The amount of electricity being generated and the total
amount of electricity generated each month can be
checked on the indoor remote control monitor. The
system also comes with an environmental monitor
function that indicates the amount of CO2 emissions
reduced by solar power generation, thus giving the user a
sense of satisfaction about using solar power.
①Solar cell module
②Power conditioner
③Panel board
④Integrating wattmeter
⑤Indoor remote control monitor
First floor
1.Entrance hall
2.Japanese-style room
3.Living and Dining room
4.Kitchen
5.Utility room
6.Laundry room
7.Bathroom
8.Toilet room
9.Nursery
10.Bedroom
Second floor
11. Balcony
12.Stockroom
13. Toilet room
Building construction
◆Building overview:
Address: Maebashi, Gunma Prefecture
Total floor area: 165.9 m²
◆System overview:
Solar power generation system 3.46 KW type
Cooling system: Air-conditioner
Heating system: Air-conditioner and kerosene fan heater
Exhaust ventilation system: Third method of ventilation
◆Heat insulator specifications:
Q value: 2.2 W/m2K
C value: 5 cm/ m²
Ceiling: Glass wool insulating material 10K 200 mm
External wall: Glass wool insulating material 16K 100 mm
Floor: Polystyrene beaded foam No. Ⅰ 94 mm
Window: Heat-insulating aluminum sash and low-E glass(heat-ulating)
South Elevation
West Elevation
Technical systems
This home, completed in 2000 and located in a residential district in Maebashi, Gunma Prefecture, is fitted with a
power generation system using sunlight. Solar power is a clean source of energy, and unlike oil and coal, is
inexhaustible and does not produce CO2 emissions. The home was built with many factory-prefabricated members
which were then assembled at site. In recent years, house manufacturers such as ourselves who sell and build
prefabricated houses have been playing a leading role in encouraging the replacement of the solar power system that
must be installed on top of the roof, with roofing material that has built-in solar cells, both for improving roof designs
and reducing the cost.
Marketing strategy
This two-story home, with a total floor area of 165.9m2, is built with light-gage steel. Out of the total construction cost
of approximately 30,000,000 yen the solar power system cost approximately 2,460,000 yen of which a loan of 500,000
yen was provided by NEF (New Energy Foundation). The heat insulator specifications meet the next-generation’s
energy saving criteria (Region III) and an entire building ventilation system was adopted.
The amount of electricity generated by the solar power system during the day usually exceeds the amount of electricity
used (see the figure below). For promoting wider application of solar power generation, a system is now in place to sell
surplus electricity to electric power companies (electricity sales). (During nighttime hours, however, electricity is
bought from electric power companies as usual.)
Energy performance
Since such selling and buying of electric power automatically take place at almost uniform selling and buying rates, the
electricity generated by the house is directly reflected on the electricity bill. Since higher rates are applied when
calculating electricity charges as the amount of electricity consumed increases, introducing the solar power system
helps reduce not only the amount of electricity that must be bought from the utility company, but also the buying rate,
thus producing synergistic effects in reducing the cost.
During a one-year period, this home, for example, used approximately 10,500 KW of power, of which 1,000 KW was
generated by the house, and 2,500 KW of power was sold to the power company. This means that this household was
approximately 33% self-sufficient in electricity. Degree Day(20-12) for heating : 2231,Degree Day(18-18) for heating:
2134,Degree Day(24-24) for cooling: -165
Annual amounts of electricity consumed and sold (KWh)
8000
7000
6000
5000
4000
3000
2000
1000
0
Electricity consumed
(during the day)
Electricity consumed
(during the night)
Generated electricity used
Generated electricity sold
Changes in the Monthly Amounts of Electricity Used (2001)
1400
1200
1000
kWh
800
600
400
200
0
Jan
Feb
Mar
Apr
May
Electricity consumed (the day)
Jun
Jul
Aug
Sept
Electricity consumed (the night)
Oct
Nov
Dec
Generated electricity (used)
Changes in the Monthly Amounts of Electricity Generated (2001)
1400
1200
1000
kWh
800
600
400
200
0
Jan
Feb
Mar
Apr
May
Jun
Jul
Aug
Sept
Oct
Generated electricity (used)
Nov
Dec
Electricity generated
SEKISUIHOUSE,LTD. TOKYO TECHNOLOGY DEPATMENT
SHINJUKU MAYNDS TOWER. 1-1. YOYOGI 2-CHOME SHIBUYA-KU. TOKYO. 151-8070 JAPAN
TEL03-5352-3551 FAX03-5352-3179 http://www.sekisuihouse.co.jp/
www.iea.shc.org
www.ecbcs.org
Waaldijk, Dalem
The Netherlands
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
The project
Because of the river water coming down from the
Rhine, the river dikes almost collapsed in 1995. So
a special law was accepted to strengthen and raise
the Dutch river dikes. Because of this, the
inhabitants of an old house in Dalem, on the inside
hang of the dike, lost their nice view over the Waal
river, an old castle and the little old town on the
other side. In the end they decided to build a new
more comfortable private house on the same
location, to give them back their magnificent view.
Besides this, due to a visit to a few passive solar
houses in Germany, the new house had to be based
on passive house technology. Because of the
limited building volume (544 m³), the new house
was build (2000) on piles in the dike.
Objectives
This had to be a house for the future, with easy
access for elderly people, a so called lifecycle
resistant dwelling, where they could live as long as
possible in a comfortable and healthy way in
combination with low costs for energy consumption
and maintenance based on the energy efficient
PassiveHouse technology.
Building construction
The light weight concrete main structure of the
extended walls is covered with 300 mm EPS
insulation and finished with a mineral plaster
(u=0,115 W/m²K); insulated window frames,
windows and doors (u=0,68 W/m²K), together with
integrated sun shading systems in the large south
and west facing windows; 300 mm EPS roof
insulation (u=0,116 W/m²K) on the roof and 300 mm
EPS insulation on the floor (u=0,113 W/m²K) make
a perfect insulated envelope around the living areas
of this passive house of which the exterior building
connections are designed to avoid thermal bridges.
The living room, kitchen, bathroom and main
bedroom are connected with the main entrance,
which can be reached by a long walkway from
the road on top of the dike. The living room and
the kitchen have access to a transparent balcony
and a steel and wood terrace structure;
underneath the overhang of the main floor is
space for car parking.
Technical systems
Through a horizontal earth heat exchanger of
about 30 meters in the dike, fresh air flows into
the ventilation and heating system which easily
covers the total energy needed for space
heating.
A system with heat recovery and auxiliary space
heating using a water to air heat exchanger
applied to the fresh air intake. And also the use
of renewable solar energy for domestic hot water
heating demands.
A special, insulated body shaped, bath lowers
the demand for domestic hot water energy, that
is mainly collected by 4,23 m2 of flat solar
collectors on the roof. There are only two small
radiators, one in the basement and one in the
north west facing bathroom.
This house was built as a pilot project by the
Dutch Foundation of Passive House Holland.
This foundation was formed to encourage the
development and realization in Holland of the socalled ‘Zonhuizen’, special solar houses based
on the passive house technology (already in use
mainly in Germany and Austria) as one of the
most promising energy concepts for the future.
The foundation was formed in 1998 by 8 companies in the building sector: 5 manufacturers, 1 installation
company, 1 consultant in installations and building physics and 1 architect. After having completed two pilotprojects – ‘Heilig Huisje’ in Sliedrecht and this dike house in Dalem – the first major passive house project in the
Netherlands is at this moment being built in Sliedrecht, for sale in the open market.
Energy performance
Because of the little compact shape of the house and the relative large exterior surface, due to being built on
piles, this project didn’t quite reach the passive house targets; and energy performances (current Dutch
standards).
Reference calculations based on the EPC calculations, including assumption appliances:
EPC 1,0 (NL)
- Heating of space and ventilation air
89 kWh/m²a
- Domestic hot water
30
- Fans and pumps
15
- Lighting and appliances
79,7
Total primary energy demand
213,7kWh/m²a
EPC 0,47 (NL)
The annual primary energy demand based on EPC calculating:
- Heating of space and ventilation air
12,9 kWh/m²a
- Domestic hot water
13,4
- Fans and pumps
15
- Lighting and appliances (assumption)
79,7
Total primary energy demand
121,-kWh/m²a
PHPP (D)
The following calculations are based on the spread sheet calculation test for the passive house planning package
(PHPP). These very detailed calculations and assumptions from the PH Institute in Darmstadt are more in
harmony with this passive house technology for very low energy consumption and the annual energy demand:
- Heating of space and ventilation air
25kWh/m²a
- Domestic hot water (solar energy covers 55% of the demand) 15,1
- Fans and pumps
18,9
- Lighting
11,7
- Appliances
48,0
Total primary energy demand
118,7kWh/m²a
First monitoring results 2001 – 2002, Passief Huis Dalem (BEC 13-01-03):
- Heating and space / vent.air
31 kWh/m²
- High appreciation, especially of the indoor climate conditions, by the occupants
Costs and benefits
Net building costs, including taxes: € 190.000,-, this
makes the house, as compared to the reference
standard of conventional houses, competitively
priced. This first home in Holland based on the
PasiveHouse technology was built without any
financial support. The monitoring was financed by
NOVEM (the Dutch national institute for energy and
environment).
Project data
- net floor area 127m2
- heating volume 323m3
- building volume 544m3
- u-values
- exterior walls 0,115 (W/m²K)
- ground floor 0,113
“
- roof construction 0,116 “
- windows wood 0,68
“
- glazing triple Argon 0,60 “
- design 1998 – 1999
- realization 2000
- monitoring 2002 – 2004
Information and contactperson
Private principal - Mrs. v.Duyvenbode and Mrs. M.
Ploegmakes
Architect (contactperson) - Franke Architekten BV
(proj.arch. ir. Erik Franke)
Nijverheidsstraat 52
3371 XE Hardinxveld-Giessendam
tel.: 0031-184420170 fax.: 0031-184411908
email: [email protected]
Building, serv.,techn. - Aannemings bedrijf J.A.de
Jager
Groot-Ammers
List of publications
300 EPS 20
300 EPS 20
300 EPS 20
(insulated)
www.iea-shc.org
- De Dordtenaar febr. 2001
- Bouwwereld nr. 4 / 01
- Tijdschrift leefomgeving nr. 1 / 01
- Home juni 2001
This house was one of the five, and the only
privately owned, projects nominated for the
prestigious national award for inspiring principals
2003 for the stimulation of architecture in the
Netherlands.
www.ecbcs.org
Casco-zonnewoningen
Groenlo, the Netherlands
10,8m
2,4m
10,8m
4,2m
4,2m
N
2,4m
first floor
4,2m
sunspace
2,00m
roofgarden
4,50m
sunspace
11m
4,50m
4,2m
second floor
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
AS
U=0.17W/m2K
trekplaa t span t 150/75
"muurplaat" 140/140
ankers h.o.h. 2000mm
w.r.c. 18x135
140 mm holle baksteen wa rmtewand
rachels 22x50
damp open stuclaag 1 0 mm.
gebitumineerd board
(waterkerende laag )
146 mm. cellulose isolatie
stijl & regelwerk 40x14 6
U=0.22W/m2K
6 mm. multiplex
70
18 22 18
6
146
70
140
352
V3
rachels 24x48
vu ren rabatdelen 18x135
rachels 22x50
gebitumineerd board
(waterkerende laag)
146 mm. cellulose isolatie
stijl & regelwerk 40x146
6xmm . multiplex
U=0.20W/m2K
40 mm. cellulose isolatie
12,5 mm. gipskartonplaat
50
opbouw voor wandve rwarming (o ptioneel)
vezelcemen tboard
(gesch ilderd)
schuimbeton kwaliteit M 3
40 mm foam glass
225
gasbeton
U=0.14W/m2K
schuimbeton kwaliteit M 1
The project
The four buildings are designed as houses to live in
and to work in. All four houses are different and
could be partitioned to the inhabitants demands. The
houses were designed to fit in perfectly in the
landscape situated just ouside the centre of the
small Dutch town of Groenlo, near the German
border. A great deal of attention was put into
sustainable aspects. Mostly recyclable and natural
materials were used. Untreated wood was used on
the outside and untreated tree trunks are used as
support structures. Vegetation grows in the garden
on the ground floor, but also on first floor level.
Sustainable energy is provided by 70 m2 of solar
cells, which forms the roof of the communal parking
space. A sun space is located in each house. This
area shelters the entrance from weather conditions
and pre-heats ventilation air. DHW is generated
through an exhaust-air heat pump. A communal
condencing boiler supplies the hot water for the lowtemperature wall heating system.
Site description
The houses are situated in a semi-suburban setting.
The location is just outside the centre of a small
Dutch town, near the German border. The houses
stand on a former agricultural plot and were
designed to blend into its surroundings.
Building structure
The houses have a ground floor and a first floor.
The entrance of the house is through a sun
space covering the complete height of the
building. The sun space serves as a wardrobe
and provides in some houses access to the
lavoratories. Except in one house the kitchen
and main living quarters are situated on the first
floor. The bedrooms, bathroom and office are
located on the ground floor.
Building construction
The foundations are made of foamed concrete.
The façades are constructed with a wooden
skeleton with 140 mm cellulose insulation and
extra insulation of 40 mm cellulose on the inside.
The outside finishing is done in deal and red
cedar. The inner walls are made of hollow bricks,
for their low mass and for the in-wall heating.
The first-level floor is made of wood with a
floating cover floor. The roof is constructed of
wood. The flat roof has 195 mm cellulose
insulation and the arched roof 220 mm cellulose
insulation. Roof covering is EPDM. The flat roof
has vegetation.Only European wood was used.
Depending on the load, deal, pine or Oregon
pine was used.Swedish natural paint was used
for the pine on the façade.
Photos and graphs
Technical systems
Ventilation:
The houses have a natural inlet of air. The inlet to
the living quarters is mainly through the sun space,
whereas the inlet in the sleeping quarters can
additionally be done through direct openings to the
outside. There is an automatic exhaust. Exhaust air
is utilised by a heat pump for DHW.
This system was chosen as in such “natural houses”
a mechanical system is completely out of place. The
sun space yields direct energetic gain because of
the natural ventilation.
energy supply system
Heating through a low-temperature wall system fed
by a common high-efficient boiler. The boiler runs
on natural gas.
The heat distribution between the houses is via a
small common medium-temperature grid.
DHW through an electric heat-pump on the exhaust
air.
solar energy utilization
70 m2 solar panels (4200Wp)
Sun space over two floors for pre-heating of
ventilation air. Inlets very low and complete in the
top of the sun-space to prevent over heating.
Restriction of amount of sun by horizontal shutters.
The sun space can very efficiently be thermally
isolated from the house.
Ample daylight in all living quarters.
Energy performance
Total energy demand per house:
Heating of space:
Pumps
Domestic hot water
Ventilation
Cooking
Lighting and appliances:
73,2kWh/m2y
51.9kWh/m2/y
4kWh/m2/y
17,3kWh/m2/y
Costs
Aprox.€ 300,- ex VAT/m3
Planning tools for LCA, energy performance,
solar energy design and more
Dutch “EPN”-calculation: about 50% better than
legal requirement
“New method 5000”
“Dywag” used only for the Novem report, see list of
publications
Marketing strategy
The houses were developed in cooperation with the
furure inhabitants
Further information
The project, that is finished in 2001, is an example
of an integral design of ecological living and working
with emphasis on sustainability and energy
efficiency. To preserve the special features of the
environment, the houses were designed using a
landscaping scheme.
The four coupled houses were completed with very
few internal walls. The internal divisions are done by
the inhabitants and can be changed easily in the
future, because they are not load-bearing.
The houses have possibilities for extensions (on the
flat roof).
The space surrounding the houses is divided in
three levels with decreasing level of privacy. They
are the roof-top garden, the private garden on the
front of the house and a communal garden
surrounding the buildings.
Because the houses have a living room on the top
floor, the roof-top garden is very well accessible.
Construction:
Omnis Bouwadvies
Den Haag NL
Innovative products
Publications:
Ventilation and cooling
Heat recovery unit:
Stiebel Eltron www.stiebel-eltron.nl
Novem report, januari 2004
Monitoring Casco serrewoningen in Groenlo by
moBius consult, Driebergen
Electricity
Solar PV:
stroomwerk www.stroomwerk.nl
Novem report, november 2003
Casco zonnewoningen een evaluatie by van Panhuys
& Bais architecten
Space heating and DHW
Heat pump:
Stiebel Eltrum www.stiebel-eltron.nl
Bouwwereld, nr.16 2002
Design:
Architecture, landscape and installations:
Eva van Panhuys & Rob Bais architecten
Koninginneweg 10
2243HB Wassenaar NL
www.vanpanhuysbais.com
Advice and coordination of the inhabitants:
Jaap van der Laan/ Stichting Ecologisch Bouwen
Bergambacht NL
Solar pv-system:
Stroomwerk
Deventer NL
Bouwwereld, nr.22 2002
Het houtblad, nr. 6 2002
Duurzaam Bouwen, nr. 8 2002
"Wohnbauten mit geringem Energieverbrauch“, C. F.
Müller Verlag , Caroline Hoffmann e.a. 2004
www.iea-shc.org
www.ecbcs.org
Rivierdijk, Sliedrecht
The Netherlands
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
The project
Six houses (Types D/E) out of twelve solar houses in three types (A, D en
E) have been built against the inner slope of a river dike in Sliedrecht, the
Netherlands, (20 km east of Rotterdam). This row of single-family houses
was realized for the local housing market, as part of a small project
consisting of 23 houses (12 solar houses and 11 conventional, traditional
houses) and 1 small additional office space.
The 12 solar houses were built on the principals of passive house
technology and were developed by the architect himself. He created,
especially for this reason, a company called Archidome Holland BV.
Objectives, goals
One of the main objectives of this solar project was to prove that solar
houses, designed and based on passive house technology, can compete
in the housing market in Holland on price, quality and comfort - especially
if the owners of the houses understand the purpose and the quality of the
technology involved. In this way prospective buyers will start to recognize
the additional value in sustainability, comfort and quality.
These houses are – as compared to Dutch traditional standards – an
innovative solution for the near future of sustainable housing in the
Netherlands.
Ingenious new improvements in building detailing – triple glazing, super
insulation, the lack of thermal bridges and good airtightness – together
with a smart heating and ventilating systems (high performance DHW
systems with thermal solar collecting and efficient heat recovery air
systems) reduce energy consumption and at the same time both
improves the indoor climate conditions substantially and makes a
fundamental contribution to protecting the environment.
Some of the additional energy demand can be generated – as an optional
feature – by a few photo-voltaic panels (5 m² house type E), which the
owner can put on top of the balcony frame at the front of his solar house.
Building construction
As a result of the fact that this project is built in the body of the dike which
is constructed on more than 15 m of soft peat ground below sea level,
and because of the pressure on the dike caused by heavy rainfall
upstream on the rivers Rhine and Meuse, it was necessary to make the
concrete pile foundations extremely heavy.
For that reason, the total basement is made of monolite reinforced
concrete; the upper level structures of these dike houses are mainly
made of light weight (1700 kg/m³) prefabricated concrete wall elements
and slab concrete floors. The roofs are also made of prefab concrete
hollow roof elements. In order to avoid thermal bridges, the total housebearing construction is built on the load-bearing thermal insulation
Purenite (layer of light Pu recycling foam, 0,7 – 1,8 N/mm²; x =
0,075/0,105 W/mk). The whole structure – ground floor, facade, roof – is
covered by 30 cm of polystirol insulation; excluding the basement, which
has 15 cm rigid resol foam insulation and an exterior wall of brick
masonry. The upper part of the house facades are completely covered
with mineral plaster.
The overall foundation/wall/roof construction achieves a calculated Uvalue of 0,138 W/m²K (basement floor), 0,124 W/m²K (basement facade),
0,116 (upper façade), 0,116 (roof). Special care was given to reduce the
remaining thermal bridges.
All east, south and west-facing windows and balcony terrace doors
have integrated sun-shading systems. The wooden window frames
and isolated doors (U= 0,93 W/m²K) have triple glazing (selective
surface and filled with Argon gas U-value 0,6 W/m²K).
Design Data
·net floor area
·heating volume
·building volume
Type E
125,4 m²
348 m³
486 m³
Type A
132 m²
336m³
524 m³
Technical systems
Controlled air supply and extraction with heat recovery: the heat
recovery unit (WHR 950 J.E.STORKAIR with 100% bypass, 88%
efficiency, PHI-Zertifikat), together with the F7 air filter box, the waterto-air supply air-heater unit and the gas-burning DHW system (high
performance Solar Gas Comb II ATAG), combined with the solar hot
water storage tank (200 litters, 80 l DHW + 120 l solar part storage),
connected to 4,23 m² flat plate thermal solar collector on the roof and
F7 air filtration.
The excellent air tightness of the houses is one of the essential preconditions for passive houses. During the erection of these solar
houses, the main concrete construction and the connection with
window and door frames were heavily taped shut to achieve the
necessary air-tightness, which is also crucial for passive houses in
the (windy) Dutch climate.
Energy performance
Primary energy consumption for heating and lighting. According to
the Dutch standard NEN 5128 the primary energy consumption is :
the total energy consumption of fossil fuels per year in MJ.
The energy consumption for the heating is thus defined as primary
energy consumption, during a certain period of time, needed to cover
the heating demand of a building including the losses of the service
installations. This energy consumption will be expressed in MJ per
year.
Note:
The energy consumed by heating can be influenced in the
calculation of the energy performance of buildings by a number of
measures, for example better insulation, heating of ventilation
systems with higher efficiency or the use of passive or active solar
systems.
The result of the energy performance calculation can be seen as a
reference value. The real energy consumption for the heating will be
strongly affected by users or residents and can therefore differ from
the calculated energy demand given as the result of the calculation
of the energy performance.
The primary energy consumption for lighting Qprim;vl of a fimily home
is defined as the standard value per m² of the surface area of the
building. This energy consumption is calculated according following
equation:
Qprim,vl = 22 x Ag,verwz / ηel [MJ]
The calculation value for the lighting per m² of the surface area is 6
kWh/m² per year. This is approximately 22 when converted to MJ en
rounded off. This value can be found in the equation above.
The energy consumption of home appliances such as TV’s and washing
machines is not taken into account in this value. The electric energy
efficiency according to the Dutch standard NEN 5128 is ηel = 0.39.
Note:
The real energy consumption for the lighting can differ from the predicted
energy consumption for the building’s energy performance as a whole.
For example, the use of energy-saving lamps can affect it. The energy
performance of any new Dutch house has to conform to the Dutch
building standards for energy efficiency in the building environment. This
means that the design of each new house, according to the national
building code, must have a calculated energy efficiency performance
coefficient (EPC) of 1.
Reference calculations Type E based on the EPC calculations, including
assumption appliances:
EPC 1,0 (NL)
- Heating of space and ventilation air
- Domestic hot water
- HFns and pumps
- Lighting and appliances
Ttotal primary energy demand
87,6 kWh/m²a
42,1
14,9
50,9
195,5kWh/m²a
The design of these solar demonstration houses reaches an EPC of 0,42,
this is an improvement of 58%.
EPC 0,42 (NL)
The annual primary energy demand based on EPC calculating:
- Heating of space and ventilation air
10,9 kWh/m²a
- Domestic hot water
20,1
- Fans and pumps
14,9
- Lighting and appliances (assumption)
50,9
Total primary energy demand
96,8kWh/m²a
PHPP (D)
The following calculations are based on the spread sheet calculation test
for the Passive House Planning Package (PHPP). These very detailed
calculations and assumptions from the PH Institute in Darmstadt are more
in harmony with this passive house technology for very low energy
consumption and the annual energy demand:
·heating of space and ventilation air
15kWh/m²a
·domestic hot water (solar energy covers 55% of the demand) 21,9
·fans and pumps
15,1
·lighting
11,5
·appliances
53,6
Total primary energy demand
117,1kWh/m²a
Costs and benefits
The calculated building costs turned out to be € 1.285,- / m² for the 12
solar houses. After the restricted tender, the real building contract was
closed at € 1.153,- / m²; this means: the real costs € 132,- /m² for the 12
solar houses were more than 10% less than calculated. The calculating
costs for the traditional Dutch reference houses were € 1.089,- / m² ; after
the tender, the contract costs were € 1.101,-; so the 11 conventional
houses + € 12,- / m² , which is a little bit (1%) higher than calculated.
Conclusion
The first careful conclusions show us that in this project the building costs
of these 12 passive solar houses are 4,7% higher compared to the Dutch
standard building costs for the 11 conventional houses in Sliedrecht built
on the same site at the same time in the same housing project.
Marketing strategy
To market this project, no special information was given about the high
performance of the 12 solar houses. Just the usability of the plan, the
location in the dike (more privacy), the living conditions and the good
price/quality relation convinced the new owners to buy all these 12 solar
houses, which were sold before the completion date. The only
information, given in the prospectus, was about the ‘zonhuis’ quality:
·no traditional radiator heating system, but a controlled hybrid heating
system by ventilation air and, in reserve, 3 small radiators in the sunmissing basement, the bathroom (extra comfort) and the living room.
Summary
The comfortable indoor living conditions, in combination with lowoperating costs for heating consumption, makes these houses ready for
the future; they are user-friendly, have a positive performance in their
building environment, and protect the quality of their and others’
environment by using appropriate technology in combination with good
architecture.
Information and Contactperson
Developer
Architect
Building, serv.,techn.
Stimulation, funding
- Archidome Holland BV (proj.manager
M.Bezem)
Hardinxveld-Giessendam
- Franke Architekten BV (proj.arch. ir.
E.Franke)
Hardinxveld-Giessendam
- Consultant installations and building physics
J.P.v.der Weele BV, Groningen
- Brouwer Energy Consultant BV, Apeldoorn
- Ingenieurbüro Morhenne GbR, Büro für
umweltverträgliche
Energiesysteme, Wuppertal
- Foundation Passive House Holland,
Bruchem
- NOVEM, national institute for energy and
environment, mr.dr.L.Brouwer, Utrecht
List of publications
·Passive House Holland Foundation stimulates innovative building
technology; Bouwwereld nr. 4 (febr. 2001), pag. 36 – 39
·Solar home, good practice and smart building; 10 owners about energy
saving and comfort, NOVEM jan. 2003, pag. 34 – 35
www.iea-shc.org
www.ecbcs.org
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Budstikka 18
Kongsberg, Norway
IEA – SHC Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
Plan of main floor.
The project
A single family house is being built in the central
eastern part of Norway. The house is 300 m2
including the main part, a small apartment for rent,
and a home office. The construction will be
completed during summer 2004.
The house is situated in a family friendly area with
limited traffic. As many trees as possible are being
kept on the site as part of the green design of the
building.
Objectives
Low energy demand and low environmental impact
has been focused from the start of the planning
phase. Auxiliary energy demand should be less than
half of average energy demand for the same type of
houses built according to the Norwegian building
code. The energy demand for room heating should
be reduced with 75%. The climate is typical inland
climate with low humidity, little wind, cold winters
and fairly warm summers.
The energy design should also result in a robust and
user friendly home with good indoor climate. The
project should be cost effective in a way that make
the concept interesting for other builders.
Building construction
Several measures will be carried out to improve
the building envelope compared to normal
building standard. All of these actions are
optimized in the regard of energy and cost
efficiency, and the total concept is crucial for the
good result.
Windows are triple glazed with argon gas and
two low emission coatings, wooden frame and a
total U-value of 0.95 W/m2K. Two large windows
have krypton gas and a U-value of 0.85 W/m2K.
Entrance doors have a U-value of 0.8 W/m2K.
Exterior walls have 250 mm insulation and a
U-value of 0.16 W/m2K.
Roofs have up to 400 mm insulation and a
U-value of 0.10 W/m2K.
Floors on the ground are insulated with 250 mm
expanded polystyrene and have a U-value of
0.11 W/m2K.
Thermal bridges are minimized by the use of 50
mm insulation on wooden construction details
and 100 mm insulation on concrete details. The
infiltration loss is minimized by the use of double
wind proofing and focus on air tight details
between wood and concrete and round the
windows.
Detail from connection between
Foundation and exterior wall.
Technical systems
Ventilation is provided by a building integrated
mechanical ventilation system with a rotating heat
recovery unit with an efficiency of 82%. The ducts
are short and placed in inner walls to prevent that
the exterior walls are weakened. Electricity use for
fans is low. SFP is 1.5 – 1.8 kW/m3/s.
Energy performance
The net energy use for the main dwelling of 223m2
is calculated to be 50% lower than for a similar
dwelling built according to the Norwegian building
code.
To reduce the electricity demand, A-labeled
equipment for washer, refrigerator and lighting are
used.
Energy use (net)[1]
Heating of space and ventilation air: 16 kWh/m²a
Domestic hot water: 30 kWh/m²a
Fans and pumps: 5 kWh/m²a
Lighting and appliances: 34 kWh/m²a
Total net energy use: 85 kWh/m²a
Delivered energy[2]
Calculated delivered energy: 85 kWh/m²a
A user friendly and simple control system is
installed. For each floor all the lighting can be turned
of or dimmed with one switch. A display with
possibility to turn down the ventilation is located by
the entrance door.
Energy demand for heating will be very low and the
heating installations are reduced to a minimum.
Only one electric heater is located in the living area,
and bathrooms has electric floor heating. This
simple heating installations will be sufficient
because the ventilation system will distribute the
heat to all rooms and there is no need for heaters
under the super insulated windows.
Wood from the building site will be used for heating
on very cold days. This free wood should be enough
for about ten years of consumption. The fireplace is
energy efficient and result in clean combustion.
1] The efficiency of the energy deliverance system is
not taken into account.
[2] Energy supplied to the building, in form of
electricity, oil, bio-fuel, gas, district heating, etc.,
taking into account the efficiency of the energy
systems. The energy produced by the building itself,
for example using solar water heater, photovoltaic
systems, heatpump or co-generation and delivered
back to the market is subtracted.
Planning tools
Simulations of energy demand and indoor climate
are done with the simulation tool SCIAQ Pro 2.0.
(ProgramByggerne, www.programbyggerne.no)
Costs
The extra costs are estimated to be 2% higher than
for a standard house, taking into account reduced
cost for heating system. With the reduced energy
cost the payback time will be 3-4 years.
Innovative products
Building envelope
WIndow: NORDAN: 3 pane, 2 low-e coatings,
krypton gas and stainless steel spacer.
www.nordan.no
Ventilation
Air hanling unit: Villavent VR 400 EV,
Rotary wheel exchanger with 82 % recovery rate,
www.villavent.no
Financing
The energy design is carried out and financed by the
builder and owner of the house. No financing
support is given. Results from the project IEA SHC
task 28, Solar Sustainable Housing have been
important for the pre design, though. IEA Task 28
was financed by NFR (The Norwegian Research
Council), Enova, The Norwegian Housing Bank and
SunLab/ABB. This brochure is financed by the same
project.
Project team
Owner: Hanne and Tor Helge Dokka
Builder: Tor Helge Dokka
Architect: Ellen Nesset, M.N.I.L.
Contractor electricity: Forenede montører AS,
Kongsberg
Contractor Plumbing: Rørleggermester Roar
Omholtl
Ground work: Terje Sollid AS
Masonry work: Murmester Hellik Dokka og Kjell
Dokka
Contact person
Tor Helge Dokka, SINTEF ([email protected])
Literature
T. H. Dokka, T.D. Pettersen, B. Helleren, “Forslag til
energimerkeordning for nye boliger - forprosjekt”,
SINTEF Rapport STF A03503, March 2003.
www.iea-shc.org
www.ecbcs.org
Husby Amfi
Stjørdal, Norway
IEA – SHC Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
Three room apartment, 73 m2
The project
Two buildings with a total of 51 apartments are
being built in Stjørdal north of Trondheim in central
Norway. The buildings are owned by a housing
cooperative presently consisting of three buildings
from 1970. The existing buildings have 110
apartments. The construction of the new buildings
started in March 2004 and will be completed during
the fall of 2005.
The apartments are planned for wheelchair users
and the buildings have lifts and parking spaces in
the basement. Most of the apartments have two or
three bedrooms, some have three bedrooms and
one apartment has four bedrooms. The average size
is 72 m2. The buildings are south facing with a nice
view and are not exposed to any kind of shading
from hills or other buildings.
Objectives
Low energy demand and low environmental impact
have been focused from the start of the planning
phase. Auxiliary energy demand should be less than
half of average energy demand for the same type of
apartments built according to the Norwegian building
code. Energy demand for room heating should be
very low and heating of domestic hot water should
be covered with renewable energy.
The energy design should also result in robust and
user friendly homes with high quality indoor climate.
The project should be cost effective in a way that
make the concept interesting for other builders.
Building construction
Several measures will be implemented to
improve the building envelope compared to
normal building standards. These measures are
optimized as regards energy and cost efficiency.
Windows are triple glazed with argon gas and
have two low emission coatings, wooden frame
and a total U-value of 1.0 W/m2K.
Entrance doors have a U-value of 0.8 W/m2K.
Exterior walls have 250 mm insulation and a
U-value of 0.16 W/m2K.
Roofs have up to 400 mm insulation and a
U-value of 0.10 W/m2K.
Floors on the ground are insulated with 250 mm
expanded polystyrene and have a U-value of
0.11 W/m2K.
Thermal bridges are minimized by the use of 50
mm insulation on wooden construction details
and 100 mm insulation on concrete details. The
infiltration loss is minimized by the use of double
layers of wind proofing on exterior walls and
focus on air tight details between wood and
concrete and around the windows.
Wall: 250 mm mineral wool
Roof: 400 mm mineral wool
Slab on ground: 250 mm EPS
Floor against parking garage: 300 mm mineral wool
Air tightness: below 0.8 ach
Thermal bridge value: below 0.03 W/mK
Technical systems
All apartments have mechanical ventilation and heat
recovery with 75% efficiency or better. To reduce
the electricity demand, A-labeled equipment for
washing machines, dryers, refrigerators and lighting
are used. Electricity use for fans are low (specific
fan power: 2.0 kW/m3/s).
The building site is south oriented and the solar
energy is passively exploited. Most of the windows
are south facing, extra heat will be stored in
exposed concrete in ceilings and interior walls.
Exterior shading and overhangs is used to avoid
overheating and need for cooling. Cross ventilation
can be carried out by opening windows that are
located on the upper parts of the walls.
A user friendly and simple control system will be
installed. A display with possibility to switch between
“home” and “not home” is located by the entrance
door. The “not home” position will result in lower
temperature, less ventilation and that light and
electric equipment is turned of. The display will also
show the actual energy use compared to the
calculated energy use.
Energy need for heating will be very low and the
heating installations are reduced to a minimum.
Only one electric heater is located in the living area,
and the bathroom has electric floor heating. These
simple heating installations will be sufficient
because the ventilation system will distribute the
heat to all rooms and there is no need for heaters
under the super insulated windows.
To supply hot water, a heat exchanger and a heat
pump will use heat from the grey water. This system
reduces the electricity demand by 80% compared to
a conventional electric hot water heater.
Energy performance
The net energy use for an average apartment of 73
m2 is calculated to be 40% lower than for the same
apartment built according to the Norwegian building
code. The delivered energy use, with the free heat
from the gray water taken into account, is reduced
by 60% and the heating energy is reduced by 75 %.
Energy use (net)[1]
Heating of space and ventilation air: 16 kWh/m²a
Domestic hot water: 35 kWh/m²a
Fans and pumps: 5 kWh/m²a
Lighting and appliances: 33 kWh/m²a
Total net energy use: 89 kWh/m²a
Delivered energy[2]
Calculated delivered energy: 61 kWh/m²a
1] The efficiency of the energy deliverance system is
not taken into account.
[2] Energy supplied to the building, in form of
electricity, oil, bio-fuel, gas, district heating, etc.,
taking into account the efficiency of the energy
systems. The energy produced by the building itself,
for example using solar water heater, photovoltaic
systems, heatpump or co-generation and delivered
back to the market is subtracted.
Planning tools
Simulations of energy need and indoor climate are
done with the program SCIAQ Pro 2.0.
(ProgramByggerne, www.programbyggerne.no)
Simulations of daylight levels are done with the
program Leso-Dial 3.1.
Costs and benefits
The extra costs for the energy concept, taking into
account reduced costs for the heating system, is
calculated to be 4-6% higher than for standard
apartment buildings. This extra costs has a payback
time of 5 to 10 years.
Innovative products
Building envelope
Window: www.nordan.no
Door: www.nordan.no
Ventilation and cooling
Heat recovery unit: Villavent VR 400 EV,
www.villavent.no
and Flexit K3, www.flexit.no
Controls
Unit for control of lighting, heating and ventilation
and visualization of energy use, www.ctm.no
Space heating and DHW
Heat pump: Gray water heat exchanger and heat
pump, www.menerga.no
Financing
The energy concept design is financed by The
Norwegian Housing Bank. Results from the project
IEA SHC task 28, Solar Sustainable Housing have
been important for the pre design. This project is
financed by NFR (The Norwegian Research
Council), Enova, The Norwegian Housing Bank and
Sivilarkitekt Røstvik AS/SunLab/YIT (ABB). Results
from the project “Passive Climatization” is also used
and this project is financed by NFR. This brochure is
financed by Enova.
Project team
Builder: Husby borettslag, Stjørdal
Architect: Arkideco AS, Stjørdal
Main contractor: Primahus AS, Stjørdal & Frost
Entreprenør AS, Trondheim
Contractor electricity: Siemens, Trondheim
Contractor HVAC: ELNAN AS
Project leader: Prosjektutvikling Midt-Norge AS,
Stjørdal
Building Consultant : Reum & Laugtug (Siv.Ing.
Bjørseth AS), Stjørdal
Energy consultant: SINTEF avd. Arkitektur og
byggteknikk
Contact persons
Tor Helge Dokka, SINTEF ([email protected])
Grethe Mahlum, Arkideco AS ([email protected])
Literature and links
T. H. Dokka, G. Mahlum, M. Thyholt, “Forslag til
energikonsept for Husby Amfi”, SINTEF Rapport
STF22 A02520, September 2002.
T. H. Dokka, G. Mahlum, “Valgte tekniske løsninger
og simulering av energibruk og inneklima ved Husby
Amfi.”, SINTEF rapport STF22 A03508, May 2003.
Enovas
Byggoperatør,
“Bygningsnettverkets
energistatistikk, Årsrapport 2001”, June 2001.
www.iea-shc.org
www.ecbcs.org
Landskrona, Sweden
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
The project
In the south of Sweden, 35 apartments have been
built during 2003-2004. The municipal housing
company, AB Landskronahem, had an architectural
contest in 1999, and in 2003 a project team was
formed. One and a half year later, tenants were
moved in.
The team, that designed the apartments, consisted
of: project leader from the municipal housing
company, an external project leader, an architect, a
building physicist, a structural engineer, a technical
engineer, a electric engineer, a landscape architect ,
a contractor and two tenants.
The layout of the apartments are quite traditional. All
apartments have a living room, a kitchen, a
bathroom and a storage. The number of bedrooms
vary between one and four. The sizes of the
apartments vary between 70 and 115 m² usable
floor area.
The apartments are for rental, and the tenants were
moved in during the summer of ’04.
Objectives
The goal of the project was:
• to get a rental cost for the apartments of maximum
100 €/m² usable floor area during the operation
period
• to use highly thermal performance of constructions
in order to exclude conventional heating i.e.
radiators or floor heating systems
• to secure moisture proof buildings
• sustainability e.g. special solution for achieve
good air tightness, choice of materials.
Building construction
The floor construction consists of 100 mm
concrete, 350 mm polystyrene and 200 mm
macadam. The U-value is approx. 0,10 W/(m²·K).
The external walls consist of 450 mm polystyrene
and mineral wool divided in four different layers.
The external layer of polystyrene has a cement
plaster making up the façade. The framework is
made up by wooden studs and aluminum
profiles. The internal surface is covered with
gypsum board. In the wall there is also a plastic
sheet in order to make the house air tight. The
external wall has a U-value of 0,10 W/(m²·K).
The external roof is made up by light weight roof
trusses filled with 550 mm loose filled mineral
wool. The roof is covered with tongued and
grooved timber, asphalt impregnated polyester
felt, batten and finally roofing tiles. The internal
surface is covered with a plastic sheet, a thin
polystyrene board, mineral wool and finally,
gypsum board. The U-value is 0,08 W/(m²·K).
The windows are triple-glazed with low emission
coating and gas in between. The windows facing
south and west have also an extra coating in order
to decrease the solar radiation through the windows.
The g-value is 0,34. The U-value for the windows,
including frames, varies between 0,9 and 1,0
W/(m²·K) depending on window size. The glassed
area corresponds to approx. 20% of the floor area.
The window area facing south-north and east-west
are 50/50% respectively. The reason for this is that
the houses do not need a special orientation to take
care of the solar gains since the constructions are
highly insulated combined with high performance of
windows and heat recovery from ventilation.
When we need solar energy for space heating, i.e.
during winter, the gains are low. In opposite, when
we do not need space heating, i.e. during summer,
the solar gains are high. The consequence is that
the orientation of windows is of minor importance
when it comes to space heating. Instead it is
important to reduce solar radiation during late
spring, summer and early fall to prevent overheating
problems. The apartments have been equipped with
windows with low g-value and a large roof overhang,
1 m. In this way the solar gains will be limited. All
windows are operable in order to give the tenants
freedom to open them whenever they want.
The project has besides energy efficiency, dealt with
moisture and dehydration issues. The construction
has during the design phase been examined and
improved concerning moisture prevention (rain,
moisture in air, moisture from the production phase,
surface water, water in soil). The goal has been to
dehydrate the concrete constructions to 85% relative
humidity and wooden constructions to a moisture
content by mass below 18%. Measurements and
mechanical dehydration have also been made
during the construction phase.
The apartments are planned, designed and built with
high quality concerning air tightness. Special
drawings and instructions were made. Also, two
carpenters were specially engaged to explicitly work
with the plastic sheet making the apartments air
tight. A blower door test was carried out after the
plastic sheet was fixed. The air tightness was
measured as 0,1 litre/(m²·s) at 50 Pa differential
pressure – Swedish record in air tightness!
In order to prevent the tenants from penetrating the
plastic sheet during the occupation phase, the sheet
has been placed inside the construction, i.e. nails
and screws may be fixed in the gypsum wallboard
without penetrating the plastic sheet. This sheet is
placed approx. 70 mm into the construction from the
inside of the wall.
The heat capacity of the apartments are fairly low.
The reason for this is to be able to receive a good
thermal comfort even if the sun will affect the indoor
temperature. Being able to open windows, the
indoor temperature will decrease faster than having
a medium or high heat capacity.
Technical systems
Each apartment has a supply and exhaust air
ventilation system with heat recovery (air-to-air heat
exchanger). The efficiency is approx. 85%
depending on the outdoor temperature.
The very limited space heating demand is covered
by electric resistance heating, 700 W, in the supply
air.
The air flow rate is according to the Swedish
Building Code and corresponds to approx. 0,5 ach,
depending on the size of the apartment.
Household appliances, e.g. refrigerator and freezer,
as well as the hot water boiler are energy efficient.
The domestic hot water is heated by electricity.
Energy performance
The total energy demand is calculated as approx.
50-60 kWh/(m²·a). Modern apartments built during
the end of the ’90s and beginning of 2000 use
approx. 120-150 kWh/(m²·a), whereas 30-50%
stands for space heating. The savings in these 35
apartments are therefore approx. 70-90 kWh/(m²·a).
Calculated energy demand
Space heating demand
Domestic hot water demand
Household electricity
0-5 kWh/m²a
25-30 kWh/m²a
20-25 kWh/m²a
Planning tools
The indoor temperature and space heating demand
were calculated with the computer program IDA
Indoor Climate and Energy 3.0 (Equa, 2003).
www.iea-shc.org
Costs and benefits
The apartments cost not more than conventional
apartments. The cost for heating system has been
saved, and instead put on the insulation thickness and
window quality.
The minimal space heating demand reduces the
operational costs with approx. 25 %, giving a renting
cost of approx. 100 €/(m²·a).
Modern apartments built during the end of the ’90s and
beginning of 2000 have a renting cost of approx. 130
€/(m²·a).
Financing
The project is commercial and the owner is the
municipal housing company AB Landskronahem in
southern part of Sweden. No special subsidies were
received.
Project team
Concept self heating houses : W Strolz, K Adalberth
Project leader
W Strolz, prime project ab
Building Physicists K Adalberth, prime project ab
Architecture
Mernsten Arkitektkontor AB
Structural engineer B Ekström/H Larsson, WSP
Technical engineer G Nyberg, EVP i Helsingborg AB
Electric engineer
J Viberg, Elteknik AB
Landscape architect C Högard Landskapsgruppen Syd
Main contractor
B Ravemark, Skanska
Contact person
Werner Strolz
Rattgatan 7
SE-261 51 Landskrona
Sweden
phone +46 418 100 40
fax +46 418 10 998
[email protected]
Literature and links
www.primeproject.se
www.ecbcs.org
Göteborg, Sweden
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
Air tightness 0.3 ach at +/-50 Pa
Air heat exchanger, η=80 – 85% P=70 W
The project
In an environment of great natural beauty at Lindås,
20 km south of Göteborg, the city owned company
Egnahemsbolaget has built 20 terrace houses in
which a traditional heating system has been
replaced by a heat exchanger in combination with
an exceptionally well insulated construction. Solar
collectors on the roof provide half the energy
needed for the supply of hot water.
The terrace houses were designed by EFEM
arkitektkontor, and are the result of a research
project extending over four years, carried out in
cooperation with Chalmers University of
Technology, Energy and Building Design at Lund
University, the Swedish National Testing and
Research Institute (SP) and the Swedish Council for
Building Research (Formas).
The buildings were designed to provide a pleasant
indoor environment with minimum energy use. The
courtyard facade towards the south has large
windows to make full use of solar heat. Balconies
and roof overhang provide protection against
excessive solar radiation during the summer. Owing
to the terrace construction with houses of 11 m
depth, there are few external walls, and these are
exceptionally well insulated and airtight. The roof
window above the staircase gives light in the middle
of the house, and is also used for effective
ventilation in the summer.
Objectives
The goals were to show that it is possible to build
houses in a Scandinavian climate with no special
heating system and to normal costs.
Marketing strategy
There were no special efforts done to market the
houses. They were advertised as “Comfortable
row houses in a beautiful nature with a low
energy demand.”
Building construction
U- value: W/m2K
External wall:
0.10
Framed construction with 43 cm insulation.
Roof:
Masonite beams with 48 cm insulation.
0.08
Floor:
Concrete slab laid on 25 cm insulation.
0.11
Windows:
0.85
Three pane windows with two metallic coats and
krypton or argon fill. Energy transmittance is 50%
and light transmittance is 64-68%.
External door:
0.80
Technical systems: Ventilation and Heating
The exhaust air in a counter flow heat exchanger heats
supply air. It provides 80% heat recovery. In the
summer the heat exchanger can be turned off
(automatic bypass) and the house ventilated without
preheating of the supply air and by opening windows.
Part of the space heating demand is covered by heat
gains from the occupants, ca 1200 kWh/year and
energy efficient appliances and lighting, 2900 kWh/year
which partly is useful to heat the building. The
remaining space heating demand is covered by electric
resistance heating, 900 W, in the supply air.
The houses have been designed for normal
Scandinavian climatic conditions. Very low outdoor
temperatures over extended periods are rare and are
regarded extreme. In such cases the indoor
temperature may drop by a degree or two.
The houses are neither more nor less complicated to
live in than ordinary houses. If it is cold outside, the
occupants do not open the windows to create a through
draft. If it is warm and sunny, they lower the blinds or
the awnings outside the southerly windows.
Hot water supply
Solar collectors of 5 m2 per house provide the energy
for half the hot water demand. The 500 l storage tank is
equipped with an electric immersion heater to cover the
rest of the demand.
Energy performance
The energy performance of the buildings are as
calculated. The average energy consumption is
higher than the calculated according to user habits
(higher indoor temperature, more TV-sets, home
computers, stand by appliances). The variation in
energy use for the house units is large. The total
delivered energy demand varies between 45 and 97
kWh/m²a for different households. Savings
compared to houses built according to the national
building code and practice is 50 – 75%.
Heating of space and ventilation air:
(electricity)
Domestic hot water (electricity):
Fans and pumps:
Lighting and appliances:
Delivered energy demand:
Domestic hot water (solar energy):
Total monitored energy demand:
14.3 kWh/m²
15.2 kWh/m²
6.7 kWh/m²
31.8 kWh/m²
68.0 kWh/m²
8.9 kWh/m²
76.9 kWh/m²
Illustration: Hans Grönlund, EFEM arkitektkontor
Planning tools
For the energy performance, passive solar energy
design and for the indoor climate the computer
program DEROB – LTH was used (Maria Wall).
Cost and benefits
Building costs are estimated to be normal. The extra
measures in the form of greater air tightness and
insulation, adaptation to "passive solar heating" and
heat recovery in the ventilation are paid for by the
much lower costs of the heating system and the
savings in energy costs .
Financing
The project was in the planning and evaluation
phase financed by Formas and EU (through the
CEPHEUS project). Investment costs were carried
by Egnahemsbolaget, Göteborg.
Innovative products
Swedish standard products have been used.
Project team
Client:Egnahemsbolaget
Contractor: PEAB
Architect: EFEM arkitektkontor, Göteborg
Constructional engineer: WSP, Göteborg
HVAC consultant:
Bengt Dahlgren AB, Göteborg
Electrical services consultant:
Probeko, Göteborg
Site works consultant:
Landskapsgruppen, Göteborg
Those in charge of the different areas of the
research project:
Project manager: Hans Eek,
EFEM arkitektkontor, Göteborg
Energy and Building Design LTH: Maria Wall
Building Physics CTH: Carl-Erik Hagentoft and
Fredrik Ståhl
The Swedish National Testing and Research
Institute: Svein Ruud and Leif Lundin
Contact person
Hans Eek ([email protected])
Maria Wall ([email protected])
Literature and links
http://www.ebd.lth.se click “Research”
http://www.goteborg2050.nu
www.iea-shc.org
efem arkitektkontor
www.ecbcs.org
Buttisholz, Switzerland
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
Cross section
1st floor
Wall construction
Detail: wall - ceiling
Ground floor
The project
The first Minergie-P1 certified building in the canton
of Lucerne (CH) was built by the Swiss architect
Norbert Aregger in 2003. The building is located in
the small rural village Buttisholz, 20 minutes away
from the city centre. It is a privately built single
family house situated on a south-west facing slope.
The ample separation from neighbours and hillside
site afford good daylight and optimal conditions for
passive solar use.
The house is characterised by its compactness, a
large roof overhang and large windows on the south
side where all main rooms are situated.
The heated floor area SIA2 amounts to 257 m2
(including exterior walls). The ground floor contains
a spacious living area with an open kitchen and a
wood stove as well as a workroom. All rooms have
direct access to the terrace. On the first floor there
are four bedrooms and an open working space.
________________________________________
1 Swiss equivalent to the “Passivhaus” standard
2 Swiss Society of Engineers & Architects
Objectives
The objective of this project is to minimise the
energy consumption of the building while providing a
living space with highest comfort and quality. The
building is planned as a complete system including
all necessary energy measures for a passive house.
Building construction
Roof (50 cm)
Wooden planking, vapor barrier, insulation (30cm
polyurethane) with double-sided Al foil, watertight barrier (2 layers), protective felt, humus
substrate (extensive planting).
Wall (46 cm)
Wooden lightweight construction, 36 cm mineral
wool, back-vented fiber-cement exterior skin.
Floor (23.8 cm)
Cork, cement leveling grout, separating foil,
acoustic insulation (4cm), 3-layered wooden
sheet, ribs, mineral wool ( 8 cm), 3-layered
wooden sheet.
Windows
Wooden-metal frames with triple glazing.
U-Values
Roof
Walls
Floor
Windows
Glas
(g-value:
[W/m2K]
0.071
0.146
0.124
0.8
0.7
65%)
Solar thermal collectors and weather sensor on the roof
Ground preheating
Heat exchanger
Technical systems
Ground pipe preheating of ventilation air
2 PE-pipes 160mm diameter, length: 43m
Mechanical ventilation system
The supply air from the ground pipe is further
tempered by heat recovered from the exhaust air via
a counterflow heat exchanger: 260 m3/h (100 Pa),
3-step operation.
Heating
Heat is distributed by the fresh air supply, heated
with the heat exchanger. There is a wood stove
backup heating: 80% efficiency, 11 kW, 6-8 hours
burn time.
Solar thermal system
4.5 m2 collectors with an efficiency of 80% cover the
domestic hot water demand with 71%. The
remaining coverage of 29% is assured by an
electrical back-up.
The Boiler contains 400l and has a maximal
temperature of 97°C.
Controls
The project is prevented from overheating by
sensor-controlled sun shading.
Extras
The green roof and a rainwater cistern are two
additional ecological elements in the project
Energy performance
The Buttisholz project fulfills the new Swiss
MINERGIE ®-P standard. This standard is
comparable to the German Passivhaus Standard.
A MINERGIE®-P certified building uses around 10%
of the energy of a conventionally built house in
Switzerland.
Space and ventilation heating
Energy source:
Electricity, wood stove backup
- calculated -
13.3 kWh/m²a
Domestic hot water
13.7 kWh/m²a
Energy source:
Solar thermal system 71%, electricity 39%
- calculated Pressuration test
- monitored Maximal heating power
- calculated -
0.3 h-1
10.0 W/m2
Open working space on the upper floor
Living room
Innovative products
Building envelope
Window: Optiwin wooden-metal window (certified
“Passivhaus” – window), 1.A Hunkeler,
www.optiwin.ch, http://www.1a-hunkeler.ch
Ventilation
Heat recovery unit: Confoair G90, J.E.Storkair,
http://www.jestorkair.nl/
Controls
Solar and shade control: Tebis components, Hager,
http://www.hager.de/tebis/
DHW
Solar collectors: Rüesch Minisol, type BR 400,
Rüesch, http://www.rueschsolar.ch/
View from the south-east
Project team
Architect
Norbert Aregger, Buttisholz
Timber construction engineer
P. Jung, Ing für Holzbau GmbH, Rain
Heating ventilation sanitary planner
Grüter AG, Schenkon
Controler engineering
E. Häller, Elektrotechnik, Buttisholz
Civil engineer
Weilenmann u. Blättler AG, Buttisholz
Contact person
Norbert Aregger, arch. ([email protected])
Daniela Enz, AEU GmbH ([email protected])
Literature and links
www.aregger-architekt.ch
www.iea-shc.org
www.ecbcs.org
Dintikon, Switzerland
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
Cross section
First floor
Ground floor
Detail roof
The project
This first Minergie-P1 certified house of Switzerland
was built by the architect Werner Setz in 2003. It is
a privately built single family house.
The building is located in a rural area in Dintikon,
(CH). It is situated on a north-west street corner
with a neighbour to the east. The main orientation of
the building benefits from the spacious and open
agricultural field towards south. The single family
house is very compact. Two unheated outbuildings
create a south oriented courtyard and offer storage
space. This eliminates the need for a cellar.
The heated floor area SIA2 is 220 m2 (including
exterior walls). All main rooms are oriented towards
south. The ground floor contains a spacious living
area with an open kitchen, a workroom/guestroom
as well as a plant room. The first floor includes two
bedrooms and an open space.
________________________________________
Swiss equivalent to the “Passivhaus” standard
2 Swiss Society of Engineers & Architects
1
Objectives
The builders requested an optimised annual energy
balance, a smart combination of passive and active
solar energy use, modern and ecological
construction as well as a conservation -conscious
design of the site.
Detail floor
Building construction
The walls, ceiling and flat roof are in wooden
frame lightweight construction. The whole
envelope is free of thermal bridges.
Roof
Gypsum board, wooden strapping, wind barrier,
wooden beams, mineral wool insulation, wood
chip panel, sloped air gap, flat roofing
Ceiling
Gypsum board, wooden strapping, wooden
beams with cavity insulation between, acoustic
insulation, cement grout, finish flooring
Wall
Wooden lightweight construction, back-vented
untreated douglas fir exterior skin.
Windows
wooden-metal frames, triple glazing
Floor
Reinforced concrete, insulation, cement grout,
paving tiles
U-Values
Walls
Roof
Floor
Windows
(g-value:
[W/m2K]
0.113
0.108
0.083
0.74
52%)
Photovoltaics installation on the roof
Plant room: Expansion tank of the solar
collectors, boiler, compact ventilation unit
with integrated mini-heatpump and
controller for the solar system.
Technical system
Technical systems
Ground ventilation preheating
2 BP-pipes, 200mm diameter, 40m length
Mechanical ventilation
The supply air from the ground pipe is further
tempered by heat recovered from the exhaust air via
a counterflow heat exchanger.
Heating
Heat is distributed by the fresh air supply, heated
with a compact counter flow heat exchanger unit
supplied by the exhaust air heat pump. There is an
electric powered radiator in the bathroom.
Solar thermal system
4.5 m2 flat plate collectors, 320 l storage tank,
60% coverage, heat pump and electric resistance
backup.
Energy performance
Space and ventilation heating
Energy source:
Electricity
- calculated -
12.5 kWh/m²a
Domestic hot water
13.6 kWh/m²a
Energy source:
Solar thermal system 60%, electricity 40%
- calculated Electricity for technical systems
Energy source:
Photovoltaics
- calculated -
17.0 kWh/m²a
Photovoltaics
49.5 m2 grid connected, 100% coverage of annual
electricity and domestic hot water demand.
Pressurization test
- monitored -
0.35 h-1
Controls
Sensor-controlled sun shading system.
Maximal heat capacity
- calculated -
9.67 W/m2
View from the terrace towards south
Living room
Innovative products
South-west façade
Controls
Shade and wind control: Hager Tebis TS, Hager,
http://www.hager-tehalit.ch
Project team
Architect / site engineer
Architekturbüro Setz, Rupperswil
www.setz-haus.ch
Interior designer
Merz + Isler AG, Rombach
HLKK- engineer and blower-door-test
Otmar Spescha, Schwyz
Building physics
Ragonesi Strobel und Partner AG, Luzern
PV, solar thermal system planner
Ingenieurbüro Hauri, Schwyz
Rüesch Solartechnik AG, Dottikon
Space heating and DHW
Heat pump: combi unit: Aerex BW 225/2, DrexelWeiss, http://www.drexel-weiss.at
Solar collectors: Rüesch, Typ Terza, Rüesch,
http://www.rueschsolar.ch
Contact person
Werner Setz, architect ([email protected])
Daniela Enz, AEU GmbH ([email protected])
Building envelope
Window: Passivhaus-windows DW-Plus, Wiegand,
http://www.wiegand-info.de
Door: Passivhaus-door DW-Plus, Wiegand,
http://www.wiegand-info.de
Ventilation and cooling
Combi unit: Aerex BW 225/2, DrexelWeiss, http://www.drexel-weiss.at
Electricity
Solar PV: Typ Shell Solar SM 110-24, Rüesch,
http://www.rueschsolar.ch
www.iea-shc.org
Literature and links
www.setz-haus.ch
www.ecbcs.org
Konstanz
Rothenburg, Switzerland
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
Standard floor plan
(Ground floor, 1st floor, 2nd floor)
6 ½ rooms: 167.3 m2net living area
Veranda:
61.0 m2
The project
The Konstanz project was built by Anliker AG in
2002 / 2004. From the thirteen apartment buildings
seven are built to the Passivhaus standard. The
housing estate is situated in the suburbs of Lucern,
a few minutes away from the city center.
The building site is well tied into Rothenburg's
utilities infrastructure. It is surrounded by a green
belt of natural spaces which offers a high living
quality. The plan is based on the historic "Garden
City" concept. The generous separation between
buildings affords good daylighting and natural
ventilation for each apartment. The outdoor spaces
are restricted to pedestrian and bicycle traffic.
A very flexible floor plan can be easily adapted to
fulfil the individual buyer's needs. The living area of
around 170 m2 can be used as 6 ½ rooms, 5 ½
rooms, a loft or be divided into two apartments of
4 ½ rooms and 2 ½ rooms.
Objectives
The aim of the project is to provide affordable,
ecological housing with a minimum of energy
requirement. To achieve this, a conventional
structural system was modified to include all the
features of a passive house.
"Why build energy efficient housing when you can't
sell it because the units are too expensive or
architecturally unattractive?“ The response was to
design a conventional building where energy
features are unobtrusive.
The goal was to provide living space with good
architecture. Spacious and bright rooms are created
which are easily marketed.
Living room
Marketing strategy
The housing estate is promoted in a brochure
using the slogan "Rothenburg Konstanz c'est la
vie" Living in Rothenburg Konstanz - that's life! A
large photo of a happy young girl, playing on a
swing in a summer meadow is the logo of the
campaign addressing young families. This
promotional material emphasizes that the
buildings are very ecological providing a healthy
place to live.
Anliker AG selected the target group amongst
young families as the ones who were “forward
thinking”. When developing the marketing- and
communication plan, however, other factors than
environment were emphasized.
The project was wrapped in: good architecture,
trendy design, way of living, family values, happy
and healthy children, a lot of green spaces,
health focus and being responsible for the next
generation.
Using trend issues both in developing the
apartment concepts and later communicating
with the customers Anliker AG achieved an extra
promotion/marketing effect in the market for their
product – several forces stimulated the market
niche and finally resulted in good sales for the
company.
The units have been awarded the “Passivhaus
Certificate” the Swiss “Minergie-P Certificate”
and the “Swiss Building Award”. These awards
gave Anliker AG a lot of publicity in the
newspapers winning both the company and the
product extra attention in the market.
Solar collectors
Technical system
Special (Hilti) construction from wall to wall
without penetration of insulation
Building construction
The bearing wall construction consists of masonry
and reinforced concrete.
Roof
Plaster, concrete, vapor barrier, insulation
(36 cm) with aluminium backing, water-tight barrier,
protective felt, extensive green roof.
Walls
The walls are built with clay masonry units, exterior
insulation (28cm mineral wool), and a back-vented
wooden skin (S-W façade) or exterior insulation
(30cm Neopor), with plaster(N-E faceade).
Windows
The windows are triple glazed.
Floor to cellar
Floor covering, levelling cement grout, PE foil,
polystyrene insulation (3 cm), acoustical insulation,
concrete, polystyrene insulation (30 cm).
U-Values
Walls
Floor
Roof
Window
g-Value
0.104 - 0.129 kWh/m2a
0.089 kWh/m2a
0.076 kWh/m2a
0.72 – 0.78 kWh/m2a
0.43 %
Technical systems
The Konstanz project was optimized for passive
solar energy use. The highly insulated and very tight
building envelope has no thermal bridges. The
building uses around 10% of the energy of a
conventionally built house in Switzerland.
Ground pipe preheating of ventilation air
4 PE-pipes, 160mm diameter, 35 - 40m length
Mechanical ventilation system
Supply air from the ground pipe is further tempered
by heat recovered from the exhaust air via a
counterflow heat exchanger.
Heating
Heat is distributed by the fresh air supply, heated
with the heat exchanger and a central condensing
gas furnace.
Solar thermal system
Solar collectors on the roof cover the domestic hot
water demand with 60%. The Boiler contains 1000l.
Controls
The project is prevented from overheating by
sensor-controlled sun shading.
Energy performance1
Space and ventilation heating
10.8 kWh/m2a
Energy source:
central condensing gas furnace
- calculatedDomestic hot water
20.4 kWh/m2a
Energy source:
solar thermal system 60%, gas furnace 40%
- calculatedMaximal heat capacity
7.9 W/m2
Pressuration test
0.25 h-1
- monitored 1 All values refer to the Swiss Minergie-P calculations
Planning tools
"Zertifizierungsheft"
(Passivhausinstitut, [email protected])
Innovative products
Building envelope
Windows: Plastic window system CMS SIGNUM,
Kronenberger AG, www.kronenberger.ch
Doors: Thermicum 68 (vacuum insulated), Brunegg
AG / 5505 Brunegg, www.brunex.ch
Exterior Walls: Insulation Neopor, Sarna Granol /
6060 Sarnen, www.sarna-granol.ch
Walls cellar:
Misapor (insulating concrete),
Misapor AG / 7302 Landquart; www.Misapor.ch
Ventilation and cooling
Heat recovery unit: Type 7-Air, Habitus SHG 1.2,
Gebr. Meyer AG / Luzern, www.seven-air.ch/
Domestic appliances
Kitchen appliances: Elektrolux AG, www.electrolux.ch
Space heating and DHW
Solar: Solar combi boiler UFW/2, Ernst Schweizer
AG/ Metallbau/ Bahnhofplatz 11/ CH-8908 Hedingen
Contact person
Arthur Sigg, [email protected]
Daniela Enz, [email protected]
www.iea-shc.org
Project team
Architecture and Planning
Anliker AG Generalunternehmung, Emmenbrücke
[email protected], www.anliker.ch
Passivhaus calculations
Werner Betschart, HTA Luzern, Horw
[email protected]
Civil engineering
Berchtold + Eicher Bauingenieure AG, Zug
[email protected]
Wyss Bauingenieure AG, Rothenburg
Electrical engineering
Andy Schmidiger, Emmenbrücke
Heating ventilation sanitary planning
Partnerplan AG Ing. Büro für Haustechnik und
Energieberatungen, Littau, [email protected]
Landscape architecture
Dové plan AG, Luzern, www.doveplan.ch
Sanitary planning
Josef Roth, ing. Büro für Industrie- u. Haustechnik,
Malters
Literature and links
www.konstanzrothenburg.ch
www.ecbcs.org
Monte Carasso,
Switzerland
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
The project
The “Vitali-Velti house”, designed by the two
architects A. Velti and B. Vitali; is located in the
village of Monte Carasso, near Bellinzona, south of
the Alps in Switzerland. The site is in a densely
built-up area at the bottom of a south-facing valley.
The project demonstrates that low energy housing
can and has to take into account local limitations
(shape, orientation, local and distant shadowing,
etc.). Architecture, aesthetics, costs, reliability and
simplicity were all carefully considered in evolving
the design.
The house is a massive construction, two-family
semi-detached house. Each house half has
approximately 200 m2 of net heated floor area (5 ½
rooms on three floors). The main house entrance is
on ground floor. This level includes the kitchen –
dining area, which also have direct access to the
garden. The living room / office is on the first floor.
The three bedrooms on the second floor are
separated from the rest of the house. Each house
has an individual, unheated basement for the
laundry, the utility room and the storage room. The
basement is only accessible from the inside of the
house.
The house was built privately under the supervision
of the two architects that now live in it. The financing
was provided by the owner and a bank, as is normal
done for private housing.
The house was completed in 1999.
Objectives - Goals
The main motivation of this demonstration project
is to prove that it is possible to achieve superior
performance at no additional investment cost
compared to standard construction. The design
should also demonstrate that such constructions
can also be good architecture. Drastically
reducing energy consumption and environmental
impact guided their choices during the design of
the house.
Building construction
The structure of the house is massive. Each floor
is a concrete slab construction. Part of the walls
is also made of concrete. In order to reduce the
number of thermal bridges, the house bearing
structure is built inside the polystirol insulation
envelope (13 to 20 cm of insulation thickness).
The exterior of the wall is a brick masonry
construction. The overall wall construction
achieves a calculated U-value of 0.25 W/m2K.
Special care was given to reduce the remaining
thermal bridges.
Large windows have been integrated in the
south-east façade. Windows have a global Uvalue of 1.1 – 1.3 W/m2K (frame included). They
are made of two panes (selective surface / filled
with argon gas) and a wood frame.
The flat roof was partially prefabricated (10%)
and includes two layers of polystirol and
foamglass insulation . The resulting construction
U-value is about 0.15 W/m2K.
Technical systems
Fresh air is provided by means of a two-flow
ventilation system with a cross-flow heat recovery
unit, each house having an independent system.
The system operates with a constant airflow rate in
the incoming and exhaust air channels. The
simplicity of the design and its ability to guarantee
good air quality in all conditions were the reasons
for its selection.
The southeast facade has a large window area for
spaces mainly used during the day (i.e. kitchen,
dining-room, living-room and office). This provides
large passive solar gains as well as daylight. The
solar heat gains are stored in the extensive building
mass. Indoor curtains control glare. External
louvered blinds provide an effective solar overheat
protection.
The remaining heating requirement is covered by a
wood stove in each house. Heating is distributed
simply by free radiation and room air convection,
thanks to openings in the south and north areas of
the first floor.
Hot water is produced with two independent solar
hot water systems, one in each house. Each system
is sized at one square meter flat plate solar
collectors per person (4 people per house). An
electric resistance heating element in the hot water
tank delivers auxiliary heat as needed.
Energy performance
The annual heating demand of the Velti house,
referred to the energy reference area (determined to
260 m2 with outside dimensions), is measured for
the Velti house to 50 MJ/m2y for the 2001-2002
monitored year. The electric energy indexes for
ventilation, hot water and domestic use were
measured to 0.7, 6 and 34 MJ/m2y respectively.
Costs
The house construction costs no more than that of a
conventional house. The cost saving from not
installing a conventional heating system offsets the
extra cost for the superior envelope of the building,
the two air controlled ventilation units and the two
solar hot water systems.
Energy saving resulted in substantial immediate
reductions in operating costs.
Planning tools for LCA, energy performance,
solar energy design and more
Performance indicators and quality labels were the
determining factors for the choice of appliances.
Environmental aspects were considered when
information was available. The annual heat demand
of the house was calculated with LESOSAI.
Possible moisture problems in the construction were
analysed with the program LESOKAI. Shading
calculations were performed to address the problem
of summer overheating.
Marketing strategy
Thanks to the monitored project, the house is
documented with architectonic, energy, economical
and environmental aspects. This documentation is
used for the information of the Swiss Minergie
Standard in Tessin.
Innovative products
The innovative features of this project are the large
mass inside the insulated building envelope and the
natural distribution of heating energy inside the
house (natural air convection). Another point are the
solutions found to reduce thermal bridges.
But the main innovation seems to be that the project
works with very simple measures and doesn’t need
any specific innovative products.
List of publications
- B. Vitali (1999) Costruire case secondo i principi
dello sviluppo sostenibile: è possibile ! Cantieri &
Abitare, n° 7, pp. 33 – 36.
- A. Velti (2000) Casa calda a basso prezzo.
Spendere meglio, n°4, agosto 2000, pp. 6 – 8.
A. Velti e B. Vitali (2000) Ecco la casa che si calda
da sola. Casa Nostra, n° 58, Dezembrer 2000, p.
11.
-D. Pahud, M. Generelli, A. Velti e B. Vitali (2003)
Low Energy Housing in Ticino. The “Vitali-Velti”
house. Final report, Swiss Federal Office of Energy,
to be published (in Italian).
www.iea-shc.org
Contact for possible visits
Arch. Aldo Velti
viale Stazione 31
CH - 6500 Bellinzona
Phone/fax : ++41 (0)91 825 57 71
[email protected]
Arch. Bruno Vitali
Uff. Risparmio Energetico
Sezione protezione aria e acqua
Dipartimento del territorio
CH - 6500 Bellinzona
Phone: ++41 (0)91 814 37 43
[email protected]
Contact for monitoring results
Dr. Daniel Pahud
SUPSI –DCT – LEEE
Via Trevano 1
CH - 6952 Canobbio
Phone: ++41 (0)91 935 13 53
[email protected]
www.ecbcs.org
Sunny Woods
Zurich, Switzerland
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
attic
2nd floor
U-Values
[W/m2K]
Walls
0.12
Roof
0.10
Floor (cellar ceiling)
0.16
Windows (incl. Frame) 1.00
(g-value:
60%)
Cross section
The project
The Passivhaus Sunny Woods was built in
2000/2001 by the Swiss architect Beat Kämpfen.
The name of the building explains its concept. The
six-family dwelling is located on a south facing hill
close to the woods in a residential area of Zurich.
Solar energy and wooden construction were the
themes of the design.
The building consists of six spacious (200 m2),
legally and technically almost autonomous
maisonette units with an elevated standard and
price. The lower units have a small garden, upper
units have a large roof terrace. Each dwelling has
the character of a single family house and is directly
accessible from the street with a level difference of
half a storey up or down.
Parking is available in the underground garage.
Objectives
Sunny Woods”, winner of both Swiss and European
solar prizes, is the first apartment building in
Switzerland designed to achieve an annual zero
energy balance. The project is based on passivesolar design combined with the following technical
features:
- Highly insulated, airtight building envelope
- Minimised thermal bridges
- Energy efficient windows
- Efficient ventilation with heat recovery
and ground preheating
- PV-roof, grid connected thin film solar cells
- Vacuum collectors for dhw and heating
- Efficient appliances
Detail roof - north facade
Building construction
The walls, ceiling and flat roof are of wooden
frame lightweight construction. The entire
envelope is free of thermal bridges. Cellar,
underground parking and the staircase for the
exterior access are built in concrete.
Roof
Back-vented PV panels, back-vented aluminum
sheet metal roof, sloped mineral wool, glued
wooden block panels, wooden block framing,
mineral wool, glued wooden block panels,
moisture barrier, wooden furring strips, gypsum
board.
Wall
Gypsum board, wooden furring strips, with
mineral wool in between, moisture barrier, glued
wooden block panels, wooden block framing,
mineral wool, wooden composite panels,
moisture barrier, wind barrier, larch battens,
cedar siding.
Windows
Triple glazing, solarglas, krypton.
Floor
Natural stone paving tiles, levelling cement grout,
PE foil, acoustical insulation, glued wooden block
panels, wooden block framing, mineral wool,
glued wooden block panels, metal spring
hangers, mineral wool, gypsum board, sound
deadening foil, gypsum board.
South facade with vacuum collectors as balcony railing
Detail ceiling - south façade with collectors
Technical systems (per living unit)
Ground pipe preheating of ventilation air
2 PE-pipes 150mm diameter, 30m length.
Mechanical ventilation
The supply air from the ground pipe is further
tempered by heat recovered from the exhaust air via
a cross counterflow heat exchanger.
Heating
Heat is distributed by the fresh air supply, heated
with a water-air heat exchanger supplied by the
solar collectors or heat pump. There are radiators in
the bathrooms.
Solar thermal system
6 m2 vacuum collectors serve as the balcony railing,
the storage tank contains 1400 l (combined
domestic hot water and space heating).
Photovoltaics
201.6 m2 grid connected, thin film silicon cells,
80 - 100% coverage of annual domestic electricity
and electricity for domestic hot water and space
heating back-up demand.
Financing
-Swiss Federal Office of Energy:
Pilot- and demonstration project
“Passivhaus” and “Photovoltaik”
-Electric power company of Zurich:
Stromsparfonds
Photovoltaic: (thin film silicon cells
PV installation on the roof
Costs and benefits
A big part of the additional costs of Sunny Woods
compared to other buildings was due to the
photovoltaics installation on the roof. The heating
system with extra costs of around 30-40% and the
system autonomy for each apartment increased
costs as well. For the homebuyers, however, having
an individual technical system was very attractive.
Everything considered, the pure construction costs
exceeded the costs of a conventional building by
around 5 %.
Energy performance
Space and ventilation heating
Energy source:
solar thermal system, electricity
- calculated Domestic hot water
Energy source:
solar thermal system, electricity
- calculated -
14.7 kWh/m²a
8.4 kWh/m²a
Entrance north facade
Living room
Innovative products
Building envelope
Walls:Wooden block panels, Pius Schuler AG
www.pius-schuler.ch
Space heating and DHW Solar
Vacuum collectors: B. Schweizer Energie AG,
Chnübrächi 36, CH-8197 Rafz
Electricity Solar PV
Unisolar-Baekert standard photovoltaic panels à 32
Wp (amorphous silicone triple thin film cells),
Fabrisolar AG,
www.fabrisolar.ch, www.flumroc.ch/photovoltaik
Project team
Architect / site engineer
Beat Kämpfen, Kämpfen Bau GmbH, Zurich
Energy planning and domestic technique
Naef Energietechnik, Zürich
Ganz Installationen AG, Volketswil
Timber construction engineering
Makiol + Wiederkehr, Beinwil am See
Concrete engineering
Federer & Partner, Zurich
Simulations air heating system
Air Flow consulting, Dr. Alois Schälin, Zurich
Contact person
Beat Kämpfen, architect ([email protected])
Daniela Enz, AEU GmbH ([email protected])
Literature and links
www.kaempfen.com
www.iea-shc.org
www.ecbcs.org
The Zero-Heating
House, Peterculter,
Aberdeen, Scotland
IEA – SHC Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
The project
In Aberdeen, Scotland, a private development was
built in 2000. On a small semi-urban site
surrounding by conventional homes, the client
desired a home which would meet the needs of the
environment and there family in the future.
The design team were set a low budget for the
design of a four bedroom family house but were
keen for the building to compliment sustainable
targets. In the UK there have been a plethora of
showcase environmental housing yet this building
aimed to achieve an affordable yet environmentally
friendly home.
The building is an evolution of a design used
previously by the design team and this gives it a key
advantage. The building holds a specific grid layout
and has a habitable roof space to reduce costs and
reduce site waste. The building has an open plan
main area encompassing living, dining and kitchen
with an open landing area to circulate passive heat
gains vertically.
Sustainable Objectives for the design
The sustainable targets set by the design team will
be met by:
• Ensuring that environmental gain is not created
through additional expense. This is mostly
achieved by a compact design and passive
means of heating.
• The typical dedicated central heating system is
not included in the design. The money saved
from the omission of this feature is given over to
the additional cost of environmental features.
This includes:
a) Elimination of dedicated heating system
b) Heat recovery ventilation units at points of
pollution.
c) Super-insulation in the depth of timber “I”
beams using vacuum packed recycled insulation.
(U value: 0.10 W/m2K)
d) Passive solar design with thermal mass on the
floor.
e) Low E triple glazing on all windows. (U value:
1.1 W/m2K)
f) Sustainable materials, locally sourced and
from renewable sources as far as possible.
Comparison of zero-heating house with
alternatives at 2.5% discount rate
Zero-Heating House
£600
Standard House
£563
£405
£439
£400
£296 £296
£283
2
Cost (£/m )
£500
Rural Traditional
£300
£268
£268
£183
£200
£100
£8 £19 £11
£0
Capital
M aintenance &
Replacement
•Make best use of the available technology and
design to reduce energy use, waste and embodied
energy in buildings to a minimum during
construction and during occupation.
• Use local resources (human and materials) to
support the development as far as possible.
• Finally, create an acceptable and successful
design aesthetic and innovation.
Building Construction
Much of the design is not a new concept yet there is
not much residential housing in the UK which
achieves sustainable concepts affordably. The main
thrust of the idea for this building was the need for a
dedicated heating plant to be eliminated offset by
the use of between 300-400 mm insulation.
The ‘zero heating’ family home is built using timber
“I” beams that simultaneously quick to install, allow
a large depth for the insulation and are less
expensive than traditional construction. Glue has
also eliminated from the construction. The external
wall has a U-value of 0.12 W/m²·K and the roof has
a 0.10 W/m²·K.
Externally, the building is clad in locally purchased
larch cladding with clay pantiles, chosen through an
environmental life cycle analysis.
Operation
Residual
The glazing is mostly south facing, with most of the
north, east and west glazing eliminated. This will
allow daylight to enter on the south facade while
reducing the risk of heat loss on the remaining
facades. The glazing is also triple glazed, krypton
fill with low E and the roof-lights are double glazed
low E. The triple glazing has a U-value of 1.1
W/m²·K and the roof-lights have a U-value of 1.4
W/m²·K
The interior floor is exposed concrete 250mm thick,
insulated by 100mm of polystyrene insulation so as
to act as thermal mass. The floor has a U-value of
0.14 W/m²·K
The interior of the building is far more open than
would be expected, so as to allow the heat to
circulate, but the real innovation is in almost
eliminating dedicated circulation space by allowing
all rooms to run of the central living space and
balcony. As a consequence most of the interior
space is two story, which allows light to flood in for
vast periods of the day.
In addition to the added insulation, passive solar
design, thermal mass, mechanical heat recovery
fans and triple glazing a solar panel was also
installed to aid the water heating of the house. A
wood stove is also included in the central living
space as a back up during winter, though
preliminary calculations suggest that internal
temperatures inside the house over the year should
not fall below 14oC.
Analysis
The project was completed in 2000. The three
phases of research included:
1) Life Cycle Cost Analysis of the whole building,
giving priority assessment to the energy efficient
features of the design.
2) Environmental monitoring and assessment of the
interior with emphasis on heating and ventilation.
3) Post Occupancy Evaluation, for assessing the
environmental comfort of the building.
Results from the three phases has been used for
adapting later projects for the greater use of simple
energy efficient design.
In its primary aim of reducing heating costs the ‘zero
heating’ house succeeds in reducing annual heating
costs. This equates to an 80% saving over current
‘standard’ housing designed in accordance with
modern building regulations, before discounting.
Total energy costs for the ‘zero heating’ family
home, including all the energy efficient features,
succeeds in reducing combined annual energy and
maintenance bills by £300 per year (at 2.5%
discount rate). This represents a 21% saving over
current ‘standard’ housing designed in accordance
with modern building regulations.
The additional fabric insulation, triple glazing, heat
recovery ventilation units and solar powered water
heating allow for a 80% reduction in the heating CO2
emissions between the alternatives. The use of a
wood fire also complements this environmentally as
the fuel is from a sustainable source, termed as
biomass energy.
With all the energy saving features combined,
savings of up to 21% at a discount rate of 2.5% may
be obtainable on the operational costs only, and
have a quicker overall payback period of 19-21
years.
Project team
Client
Architect
QS
Engineer
Contractor
Contact person
Gokay Deveci, Chartered Architect
The Scott Sutherland School, Faculty of Design,
The Robert Gordon University,
Garthdee Road,
Aberdeen,
AB10 7QB
[email protected]
Technical systems
Mechanical Heat recovery on points of pollution, all
other systems are passive.
As a back-up system a wood fired fireplace in
located in the main living space. During analysis
this system was only used during the coldest winter
nights.
www.iea-shc.org
www.ecbcs.org
Hockerton Housing
Project, UK
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
The project
The Hockerton Housing Project (HHP) is an
innovative residential sustainable development in the
village of Hockerton near Nottingham, UK.
Completed in 1998 after three years of planning and
18 months of construction, it has been designed as
one of the first zero energy residential systems in the
UK, reducing life cycle energy to a minimum.
Maximum use of benign, organic and recycled
materials has been made in the construction and the
development is designed to be, to a large extent, selfsufficient. The houses are earth covered and have
passive solar heating without a space heating system.
A wind turbine and photovoltaic system provide all of
the energy required to run the homes. The water and
sewage system is self-contained.
It is the UK’s first earth-sheltered, self-sufficient
ecological housing development. Project members
live a holistic way of life in harmony with the
environment, in which all ecological impacts have
been considered and accounted for. The houses are
amongst the most energy efficient, purpose built
dwellings in Europe.
The Project consists of a terrace of five single storey
dwellings which are earth-sheltered at the rear
(North), such that the ground surface slopes and
blends smoothly into the field at the back. Each house
is 6 m deep with a 19 m south-facing conservatory
running the full width of each dwelling. A repeated
modular bay system of 3.2m in width was used for
ease of construction. Most internal rooms have 3 m
high French windows so they are not so dependent on
natural light.
The development is located on a 10ha site that has
a slight slope just to the south west. Previous use
of the land was essentially agricultural. The large
area has allowed incorporation of features that
enable the occupants to live in a sustainable and
self-sufficient way. This includes crop cultivation
and the rearing of small animals. It has also
allowed for large water catchment for the homes
and waste disposal via a reed-bed system.
Objectives
There were several key design objectives
regarding energy performance and sustainability:
•To reduce space heating requirement by artificial
means to zero
• To reduce CO² emissions incurred by the
existence of the development, to zero
•To be as autonomous as possible in terms of
provision of utilities, including water
•To use renewable energy sources to meet the
energy requirements of the development
•To use easily transferable construction
techniques and ready available, environmentally
responsible materials
•To provide competitive costing to conventional
housing (in the short term) with demonstrable
savings (in the medium-long term)
•To provide occupier control of infrastructure and
services with minimal maintenance
•To increase biodiversity and enhanced landscape
associated with the project
•To offset all energy requirements (including those
embodied within materials) and CO2 emissions
incurred during construction work
•To achieve all of the above with no loss of comfort
or modern amenities.
Technical Systems
Ventilation is provided by opening windows in the
external wall and glazed doors between the
house and the conservatory. In addition, each
house has a mechanical ventilation heat
recovery (mvhr) system that supplies fresh air to
living/bed rooms and extracts from the kitchen
and bathroom.
Building Construction
The development is of high thermal mass
construction with 200mm concrete block internal
cross walls on a 300mm concrete slab, a
concrete beam-and-block roof and 500 mm thick
external walls of two skins of concrete blockwork
used as formwork to contain mass concrete.
The adoption of a single sub-slab 200mm in
thickness, simplified the construction of the
superstructure as there are no movement joints.
A polyethylene waterproof geomembrane was
laid on the upper blinding slab.
Walls, slab and roof are super-insulated with 300
mm of expanded polystyrene (cfc free) with the
mass on the inside of the insulation. The roof is
covered with 400 mm of topsoil and the north
side and terrace ends are buried in the ground.
The building envelope is clay brick for exposed
exterior walls, using bricks fired from waste
methane gas. All of the internal walls are wet
plastered. There are no holes through the main
slab for soil pipes or services so the insulation
and membranes are not perforated.
The main doors and windows opening into the
conservatory are triple glazed with low-e glass
and argon filling, whilst the conservatory has
double low-e glazing.
The solar space heating is completely passive;
heat transfer from the conservatory to the house
can be facilitated by opening windows if required.
The roof, walls and floor have a U-value of 0.11
W/m2K and the triple glazed units 1.1.
Water is heated using an air-to-water heat pump
and is stored in a heavily insulated 1,500 litre
plastic tank in the utility room. The system is
maximised by drawing air from the top of the
conservatory to gain the benefit of solar heating
and uses less than a third of energy required for
a conventional system.
Other energy conservation measures include
predominant use of low energy light bulbs, laptop
computers and purchase of appliances that are
highly energy-efficient. Appliances are not left on
standby and clothes dried on conservatory racks
rather than tumble-dryers.
Space heating relies totally on heat from solar
gain and incidental gains from occupation. The
heat is stored in the mass of the buildings (e.g.
concrete/ blockwork) and released when the air
temperature drops below that of the building
fabric.
The elevation design makes good use of low
winter sun penetrating to the back of the
dwellings and provides good internal daylighting
as well as maximising on passive solar gain
through the conservatories. The trees on the
southern boundary are all deciduous so do not
block sunlight once they lose their leaves in
autumn. During the summer, shading is created
within the homes due to the high angle of the sun
- this reduces thermal gain and brightness inside,
when it is least wanted.
A 5kW wind turbine and a 7.65kW array of
photovoltaics generate almost as much energy
as used by the homes. The HHP wind turbine is
one of very few examples in the UK of a
community owned wind turbine, whereby the
owners are supplied directly with the 'clean'
renewable energy produced.
Energy performance
Marketing Strategy
The Government sponsored monitoring programme
[New Practice Profile 119] was conducted over the
1st year of occupation only (1998/1999), as part of
the Energy Efficiency Best Practice Programme.
The total energy consumption of the 5 homes during
the monitoring period was 20,500 kWh. This
represents just over 4000 kWh per house and
around 11kWh per house per day. This compares to
an energy use of about 25% of conventional new UK
housing, and only about 10% of current UK building
stock.
The homes were self-built by the occupants. Since
1998, only one house has changed ownership. In
2002, one of the homes was sold within months of
becoming available. Due to the unusual nature of the
project, estate agent services were conducted by the
project itself who contacted people that had
expressed an interest in joining HHP. The house sold
within weeks and the new occupants have happily
settled in. It is unlikely that any other homes will be
sold in the foreseeable future.
More recently the builder associated with HHP has
gone on to build a pair of similar earth-sheltered
dwellings on land adjacent to the site. These were
commissioned by the landowners. HHP continues to
be contacted weekly by individuals wanting to live in
similar properties.
Some of the internal monitoring has continued by
HHP occupants themselves.
Max/ min temps [in one house] for porch,
conservatory, main house and main house ground
slab have been recorded together with an ‘ambient’
internal air temp [taken approx. 8am each morning]
in order to give a realistic picture of the dynamics of
temperature fluctuations in the houses. These are
cross- referenced with temperature readings in the
other houses. The energy consumption of each of
the five houses is monitored on a quarterly basis.
Note the lower usages compared to the monitored
data.
Contact person
Nick White, Hockerton Housing Project Trading Ltd.,
The Watershed,
Gables Drive,
Hockerton,
Southwell,
Notts NG25 OQU
Tel: 01636 816902
Email: [email protected]
Website: www.hockerton.demon.co.uk
House
1
2
3
4
5
Adults
2
2
1
2
1
Teens
0
0
1
2
0
Children
3
3
0
0
0
Occupation profile
Key variability of facilities between homes
0
1
1
2
0
Heat pump [water]
TV[s]
Yes
Yes
No
Yes
Yes
Home working
Yes
Yes
No
Yes
No
Energy use (average over period
– 1998 -2002)
kWhr/year
300
3002
3625
3482
402
4027
2743
kWhr/day
8.22
9.93
9.54
11.0
11.03
7.51
a kWhr/m 2/year
17.6
17.65
21.3
17.5
23.6
23.68
16.2
16.25
23.6
23.69
28.6
23.5
23.55
31.7
31.78
21.6
21.65
b kWhr/m 2/year
(internal)
www.iea-shc.org
Information (Publications:)
Hockerton Housing Project Information Pack –
includes project details and its history, principles,
design, construction methodology, services and also
sections on autonomous housing and earth-sheltering
to set the project in context.
Background Document - enshrines the foundation of
the project, laying out its aims and objectives at the
earliest stage.
Land Management Plan - an operational document,
describing current usage and status (including
records of biodiversity) of the land. It defines how the
land must be developed in a sustainable way.
HHP Project Brochure - details of key aspects of
project and suppliers.
The Sustainable Community – A Practical Guide
(Hockerton Housing Project). Based on the
experience of the Hockerton Housing Project (HHP),
this 52-page guide aims to help others plan and set
up their own sustainable projects.
Sustainable Housing Schemes in the UK – A guide
with details of access (Hockerton Housing Project)Profiles over 30 schemes as key case studies with
details of access arrangements and further
information.
www.ecbcs.org
Foley House,
Rothesay, Isle of Bute,
Scotland
IEA – SHC Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
The project
In the western isles of Scotland, 14 flats have been
built in 2003-04. After a protracted feasibility stage,
where numerous housing alternatives for the site
were, this low-impact design for the site was
chosen.
The project team, the client and local planning were
keen for the natural environment and the long
standing hardwood trees on the site to remain but
for the site to have a useful purpose in providing
homes in the local area.
The building, which is circular, is not contemporary
to the area but has a key advantage. It has a low
impact on the surrounding area as it has a small and
compact plan area. It is also reminiscent of Brochs
and medieval tower designs prevalent around
Scotland. The building houses 14 flats with either
two or three bedrooms. It has an open plan main
area encompassing living, dining and kitchen areas
which lead to a terrace.
The apartments are for rental, and the tenants were
moved in during the summer of ’04.
Sustainable Objectives for the design
The sustainable targets set by the design team and
the client will be met by:
• Protecting wildlife habitat and respecting the
landscape and the distinctive identity of the
proposed location.
• Provide and encourage genuinely participative
forms of local democracy where citizens ‘own’
the ideas and the objectives and can work
actively towards those objectives. We have
adopted and promoted a holistic approach to the
design, including the wider environmental and
visual impact of the development on Rothesay,
and have fully involved the Rothesay community
in the process of design and planning.
• Strike the right balance between a reasonably
high density of activity and dwellings necessary
to support services and to provide green space
and a feeling of well being.
• Make best use of the available technology and
design to reduce energy use, waste and
embodied energy in buildings to a minimum
during construction and during occupation.
• Maximise accessibility paying particular
attention to the importance of walking and cycling
activities.
• Make a positive and quantifiable contribution to the
reduction of greenhouse gases (CO2 and others) by
using,
a). Triple glazing with super low-E and argon gas
infill (Uvalue : 1.0 W/m2K)
b). Max levels of insulation and airtight construction.
(U value: 0.12 W/m2K)
c). Heat recovering mechanical whole house system
d). Elimination of the dedicated central heating
system
e). Additional insulation to Hot water tanks (100mm
rather than 50mm)
• Use local resources (human and materials) to
support the development
• Adopt best practice for sustainable development in
the UK by DETR, 1999 through partnering etc.
• Contain the right ingredients to trigger and
encourage a reduction in car dependency
• Finally, create an acceptable and successful
design aesthetic and innovation.
Building Construction
The floor construction consists of 215 mm concrete
base, 150 mm extruded polystyrene and 200 mm
macadam. The U-value is approx 0.12 W/m²·K.
The external walls consist of 300mm cavity with
275mm Fibreglass 'Dritherm' cavity insulation or
equal with 25mm cavity . External walls are 100mm
block with render, with 140mm dense concrete block
internally. Brickwork externally to the stair areas.
The internal surface is covered with foil-backed
plaster board. The external wall has a U-value of
0.14 W/m²·K.
The roof is finished with 0.7mm preformed zinc
roofing trays with standing seam joints at 600cts
fixed with stainless steel clips on ventilated 25x100
pine sarking boards (untreated) on timber roof
trusses to SE details at 600cts. 400mm insulation
quilt and vapour barrier at ceiling level. Zinc lined
internal gutters laid to falls with proprietary rainwater
roof outlets and leaf guard. The U-value is 0.12
W/m²·K. On the terraces an Inverted roof comprising
50mm conc paving and gravel ballast verges on
150mm (roof) / 50mm (balcony) extruded
polystyrene insulation on geotextile membrane on
20mm roofing asphalt, sheathing felt on screed. The
U-value is 0.16 W/m²·K (roof terrace).
All windows to flats to be ‘high performance triple
glazed type timber casement window with external
aluminium facings. Pre-stained finish. 25mm marine
plywood box construction around window wrapped
with vapour barrier. All joints sealed with tape. The
U-value is 1.1 W/m²·K with the total amount of
glazing approximately 15% of the floor area.
The flats main glazing is in the living area leading to
the terrace, for passive solar gains. The balcony/
terrace above each flat has an overhang allowing an
element of shelter from the summer solar gains as
will the site which has, predominantly, mature
broad-leaf trees that will provide shelter from the
sun during the summer. Alternatively, the overhang
is such that the flats may gain solar benefits during
the winter.
It was important for the flats to be airtight during
construction. With this in mind the architect placed
special emphasis during construction on this issue,
especially on details around the windows and the
balconies.
Technical systems
· Passivent AV continuously operating ventilation
system is used in the building powered by
continuously running roof mounted extract fans
within Passivent louvred terminal comprising :
Extracts – Ceiling mounted extract fixed to a
ductwork system linked to a continuously running
central extract fan. Extracts provide continuous
extraction dependent upon relative humidity
response. Min extract 8m3/hr at 30% RH. Max
65m3/hr at 90% RH.
Inlets – window mounted humidity responsive inlets
complete with external canopy grille sited in
habitable rooms only.
Space heating is provided by electric Duplex dual
control heaters connected to a separate reading
meter from the common electrical mains.
Costs and benefits
The passive systems in the building as well as the extra
insulation aims to reduce space heating demand by
40% over a building meeting the current Scottish
regulations.
Financing
Dunno
Project team
Client
Architect
QS
Engineer
Contractor
Contact person
Gokay Deveci, Chartered Architect
The Scott Sutherland School, Faculty of Design,
The Robert Gordon University,
Garthdee Road,
Aberdeen,
AB10 7QB
[email protected]
Energy Performance
Dunno
www.iea-shc.org
www.ecbcs.org
INTEGER Project,
Maidenhead, UK
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
The project
The project of 27 dwellings consists of six two-bed
houses, two three-bed houses and 19 one-bed flats.
Located on a brownfield site in the centre of
Maidenhead, it was originally a car park with
concrete garages that were mostly no longer in use.
The site is ideally located for housing, being only
five minutes walk from a railway station and ten
minutes walk from the town centre.
The project was jointly funded by the Royal Borough
of Windsor and Maidenhead and the Housing
Corporation. Work on site began in 1999 and
development was completed in September 2001.
Objectives
In 1998, housing association ‘Housing Solutions’
approached INTEGER with a scheme for a site in
Maidenhead. The aim was to incorporate as many
INTEGER elements of innovation in design,
intelligence, environmental performance and
construction process as possible in order to
maximise the benefits to the future occupants. The
design incorporated many innovative environmental
features in which low energy use, and therefore low
bills for tenants, was a central theme.
U-values
(W/m2K)
Building
Regulation
requirements
at time
Roof
0.2
0.25
Exposed
external walls
0.2
0.45
Windows
2.16
3.0
Ground floor
0.35
0.45
Building construction
Timber frame was the selected method of
construction as it is sustainable and inherently
thermally efficient. The timber frame was a
170mm engineered timber I-beam, which was
filled with recycled cellulose insulation. I-beam
construction offers additional thermal benefits as
the beams prevent cold bridging.
All the ground floors were v313 chipboard on
rigid insulation on a sand base. The upper floors
were 30mm dry flooring, 22mm OSB (oriented
strand board) on engineered timber joists with
100mm glass fibre quilt between joists for sound
insulation. The ventilated roof spaces have
250mm recycled cellulose insulation fully
covering the ceiling joists.
U-values of the houses and flats were well in
excess of the Building Regulations at the time.
These are shown in the table above.
For prefabrication of pods to be cost-effective,
multiples of the same unit needed to be
produced. In this scheme, plans for the 19 flats
were amended at the design stage to enable
repetition of the bathroom and part of the kitchen.
Building construction cont …
The kitchen was also altered so that all the mains
services were located on the wall between the
kitchen and the bathroom. This gave rise to a
combined kitchen and bathroom open-ended pod
with kitchen units already attached to one
external pod end wall. A central service core
was also included.
Although prefabricated pods were used for the
flats, they were not considered cost effective for
the houses because of the smaller number of
units required. Using the pods saved an
estimated £1,000 per flat.
The use of this type of pod system was
reasonably successful, although the way in which
the kitchen end of the pod was left open made it
vulnerable to damage during storage,
transportation and installation giving rise to
issues of responsibility. It was also considered
preferable to leave off the external linings in
future pods, allowing a better finish to be
achieved. The central service core was a
success, although lessons were learnt about
making clear the division between prefabrication
plumbing and electrics and their on-site
equivalents.
The dwellings were clad in Western Red Cedar.
This is a low maintenance material requiring no
preservative treatment. It contains natural oils
and can be left without painting or varnishing for
a natural look. It also changes colour to a more
subtle silver shade; this should be considered
when specifying, and explained to clients.
In this scheme the external cladding alternated
between vertical and horizontal orientation to
give each tenant in the flats a visible exterior
boundary.
Cedar Cladding
This variation of orientation does mean high
levels of wastage and it was recommended that
this should only be carried out in future if there is
an overriding rationale for doing so, rather than
purely aesthetic reasons.
‘Living’ Green Roof
Another low maintenance sustainable feature
was the ‘green’ roof. The roof is planted with
chives, saxifrage and sedum, which are all tough
flowering alpine plants with short roots. The roof
is grown off site and is simply rolled out over a
base. The sedum offers extra protection to the
waterproofing layer and can extend the roof’s
lifetime by a factor of up to four. The plants are
able to survive in periods of drought without extra
attention.
The roof requires annual maintenance, and this
is carried out by the supplier until it is
established. The waterproofing system used is
guaranteed for 20 years.
Passive stack ventilation extracts and light pipes
were easily incorporated into the gently sloping
green roof – whilst the steeper rear up-stand
allowed for easy integration of the photovoltaic
and solar water panels.
Technical Systems
Heating and Hot Water
A 3.3m² Solar Hot Water (SHW) panel was
provided for each house. As there was
insufficient space on the roofs of the flats for both
photovoltaic and SHW panels, the PV potential
was maximised instead.
The SHW panels have an efficiency rating of
80% and expected average output of 1.126 kW/h
in the summer and 0.926 kW/h in the winter.
Each SWH panel is connected via a pressurised
circuit into a copper double feed pre-insulated
160 litre storage cylinder with double primary coil
for solar and boiler water heating. The life
expectancy of these SWH panels is in excess of
25 years, with a five year guarantee.
Energy performance
The SAP ratings on this development ranged from
90-100 (this scheme was built prior to the raising of
the maximum SAP rating from 100 to 120).
Gas provides all the heating and hot water needs;
cooking is electric. The annual gas bill for the onebed flats is currently £55 all-inclusive. This cost is
less than for a typical one-bed flat partly due to the
excellent energy performance of the buildings, but
also due to the fact that Housing Solutions buy gas
at a commercial rate through a bulk contract
covering this the Greenfields project and another 20
sheltered schemes.
Dwelling Type
No. of
dwellings
SAP
rating
Annual
predicted
heating & hot
water cost
One-bed flat
19
100
£97 (ground
floor flat)
Two-bed house
(mid terrace)
4
92
£184
Two-bed house
(end terrace)
2
96
£181
Three-bed
house (end
terrace)
1
90
£209
Three-bed
house mid
terrace)
1
100
£197
Planning tools
An analysis was made of the site’s relationship to
the path of the sun and it was decided to place the
buildings in a linear form close to the north-west
boundary. This configuration enabled all of the
homes to take advantage of the sunny aspect and of
passive solar gain. There is a contrast in
appearance between the sunny side of the
buildings, south-west elevation, which is glazed and
open and the north-east side, which has a denser
exterior with fewer and smaller openings to minimise
heat loss.
Costs and benefits
Total build costs of this project were approximately
£2.4 million.
A further cost breakdown showing the cost of
innovative features used in the project is shown
below. To help meet some of these additional costs,
Housing Solutions were able to secure DTI funding
from the 100 Roofs PV Domestic Field Trial and the
SMART Metering Programme.
www.iea-shc.org
Building Elements
Inclusive Costs
Kitchen / bathroom / airing cupboard
/ central service riser pods (15 flats) £97,000
PV system (8 houses, 7 top floor flats) £150,000
SHW system (8 houses)
£18,000
Passive stack ventilation vents
(all 27 units)
£22,000
Grey Water System (all 27 units)
£46,000
Remote Monitoring (all 27 units)
£35,000
Marketing Strategy
INTEGER is the UK's leading action-research network
promoting innovation in buildings using intelligent and
green technologies. Since 1996, over 100
organisations have joined INTEGER as partners to
find ways of delivering better performance and value
in buildings. These organisations include designers,
contractors and suppliers as well as housing
providers, government agencies and research groups.
Contact person
Alison Nicholl, INTEGER Partnership Manager,
+44(0)1923 665955
Information
Client: Maidenhead & District Housing Association
Architect: Bree Day Partnership
Intelligent Systems: i&i limited
Services Engineer: Oscar Faber
Structural Engineer: Anthony Ward Partnership
Quantity Surveyor: The Andrews Partnership
Health & Safety Planning: Chris Monckton Associates
Contractor: Bickerton Construction
INTEGER Intelligent & Green Ltd
Building 9, Bucknalls Lane, Garston, Watford,
WD25 9XX
Tel: +44(0)1923 665955
Fax: +44(0)1923 665956
Website: www.integerproject.co.uk
UK – IEA SHC Ex-co member Professor David
Strong, Managing Director, BRE Environment
Helpdesk: +44 (0)1923 664500
Email: [email protected]
Website: www.bre.co.uk
www.ecbcs.org
The INTEGER
Millenium House,
Watford, UK
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
Interior of INTEGER House
The project
The INTEGER Millennium House went from design
to construction to completion to occupation within a
period of eighteen weeks. There were no contracts
involved and no budget as suppliers donated
materials, expertise and time free of charge. This
was a real team effort with the task of building one
of the most innovative houses in the world. The
process was captured for posterity by the BBC in
the six-part, prime-time ‘DreamHouse’ series.
Since it opened in 1998, the INTEGER Millennium
House has functioned as a demonstration house,
showcasing the origins of the INTEGER concept. To
date, over 5,000 people have visited it, with glowing
commendations such as “I love it! Where can I buy
one?” It is a house which has reached iconic status
in Britain and around the world.
Objectives
Following a seminar entitled “Intelligent &
Green?” in May 1996, a design team was formed
to evaluate available design and technical
solutions to improve housing performance. This
culminated in the production of a model house
and specification which has toured the world,
showcasing what is possible in introducing
innovation to housing.
During 1998, the design team set out to turn this
model into reality. The project involved a wide
range of partners from all areas of the housing
sector, including materials and product suppliers
and building professionals. They all contributed
expertise, time and materials to the construction
of a real intelligent and green house.
The house aimed to incorporate innovation in
design, intelligence, environmental performance
and the construction process, turning a dream of
what was possible into the reality of a threebedroom house.
Building construction
Materials for the building fabric were selected for
sustainability, low embodied energy, long life and low
maintenance.
A low maintenance turf roof provides good insulation,
is visually attractive and provides a natural alternative
to conventional roof materials.
Off-site fabrication of components included pre-cast
concrete floor slabs and timber panels for the
superstructure insulated with 170mm of cellulose
recycled paper.
Integrated design and procurement. CAD drawings
were issued by e-mail from designers to
manufacturers. Pre-fabricated components were
designed and agreed in a matter of days.
Standard components from the commercial
glasshouse industry were used to construct the
conservatory.
Bathroom modules similar to those originally
designed for the off-shore oil industry were craned
into the site as fully completed timber-framed rooms.
A central service core was used to distribute all of the
pipework and cabling services vertically through the
house. Structured cabling hidden behind removable
skirting, and service voids behind the internal
plasterboard walls allow for easy access for
maintenance and upgrade.
Technical systems
A heat pump extracts energy from water circulating
in a 50m deep borehole. Although the heat pump
runs on electricity, it is very efficient using only one
unit of electricity for every three units of heat
provided.
Heating is delivered through under-floor trench
heaters. Water is pumped at 50°C to bring the
temperature up to that set by the individual room
thermostat.
Solar water heaters mounted on the roof can
provide free hot water at up to 95°C which is then
pumped to a highly insulated hot water tank at 77°C.
This water is then supplied at mains pressure
around the house as required.
A grey water system treats and recycles water used
for washing and bathing and re-uses it for flushing
the toilet, reducing water usage by around 30%
Rainwater is collected, treated and stored in an
underground tank for garden irrigation and car
washing.
Soil humidity is monitored to ensure that the
automatic garden irrigation systems only waters
plants which need it.
Energy performance
The sophisticated yet user-friendly building
management system ensures that the performance
of the heating system is optimised, only operating it
when heat is required.
Costs and benefits
The project was carried out as a demonstration with
no budget. With suppliers donating their materials,
expertise and time free of charge, it is difficult to
make realistic cost assessments on this project.
An intelligent security system not only picks up
intruders but also interacts with the lighting, heating
and door control systems to ensure that no energy is
wasted while the house is unoccupied. On returning
home, all of the systems within the house ‘wake-up’
automatically to provide safety and comfort as soon
as you step in the front door.
Project team
Architects : Cole Thompson Associates, Bree Day
Partnership, Paul Hodgkins Associates
Intelligent Systems : i&i limited
Building Services : Oscar Faber
Structural Engineer : Anthony Ward Partnership
Cost Consultant : The Andrews Partnership
Performance Measurement : Centre for
Performance Improvement in Construction, BRE
Marketing strategy
Many of the 5,000 visitors to the house have wanted
to know where they can buy an INTEGER house,
and why housebuilders are not offering this kind of
product to the public. In this way, the INTEGER
Millennium House has succeeded in creating an
example of what is possible and also permitted
people to raise their expectations of what housing
quality can be. Not merely three bedrooms under a
roof, but a tool through which lives can be improved.
The INTEGER House has received widespread
media coverage - the most obvious example being
the “Dreamhouse” series on BBC1 prime time and in
forthcoming repeats.
INTEGER is the UK's leading action-research
network promoting innovation in buildings using
intelligent and green technologies. Since 1996, over
100 organisations have joined INTEGER as
partners to find ways of delivering better
performance and value in buildings. These
organisations include designers, contractors and
suppliers as well as housing providers, government
agencies and research groups.
INTEGER Intelligent & Green Ltd
Building 9, Bucknalls Lane, Garston, Watford, WD25
9XX
Tel: 01923 665955
Fax: 01923 665956
Website: www.integerproject.co.uk
Contact person
Alison Nicholl, INTEGER Partnership Manager,
+44(0)1923 665955
UK – IEA SHC Ex-co member Professor David
Strong, Managing Director, BRE Environment
Helpdesk: +44 (0)1923 664500
Email: [email protected]
Website: www.bre.co.uk
Planning tools
The construction of the INTEGER Millennium House
was monitored by the BRE Calibre programme and
some valuable lessons were learnt. As the House
was so unique, it is difficult to make comparisons
with a conventional housebuilding programme, but
high measures of productivity, good teamwork, a
non-confrontational approach, joint ownership of
problems and good levels of interdependence
between team members were noted.
www.iea-shc.org
www.ecbcs.org
Demonstration houses in
Kansas City, MO USA
IEA – SCH Task 28 / ECBCS Annex 38:
International Energy Agency
Sustainable Solar Housing
The project
Four single family detached homes built by Envision
Development Corporation, a private corporation, are
located in Raintree Lake Estates, Lee’s Summit
Missouri, USA. These homes were build in the estate
section of this community and were built to
accommodate the infill lot cost and up-scale location.
These homes are speculative homes and are for sale.
They have also served as successful models for
prospective clients who desire building.
They range in size from 3600 to 6300 square feet of
conditioned space with 2200 to 4750 square feet of
finished area. The fourth home was finished in
September 2003.
Currently “Vision Homes” is breaking ground on a 70
acre private forest preserve near Lawson, Missouri.
This new construction is a direct result of using the
existing homes as a demonstration or showcase for the
builder.
Objectives - Goals
The goal of was to construct platinum level “Build
Green” homes as defined by local Home Builders
Association (KCHBA) utilizing Energy Star (US EPA)
and Health House (American Lung Association)
standards with universal design elements.
A whole systems approach looked at site, energy,
materials, Indoor Air Quality (IAQ) and Recycling
opportunities.
For these Missouri (USA) homes with about 5400
heating degree days we considered construction costs,
longevity, remodeling ease, maintenance and energy
usage.
Building construction
4” Structural Insulated Panels (SIPS) along with 1” EFIS
(exterior finish insulation system) were selected for wall
panels because they were less expensive to build and
were 15% more energy efficient than standard stick built 2X
6 construction. Walls as constructed have a U value of .05
or R-22. ICFS with non heat conducting ties were used
below grade with a standard 8“ concrete wall thickness.
2nd generation SIPS with fiber concrete outer walls is being
used on current and future build jobs to reduce labor costs
Basement insulation is 2-2" layers of R-Control EPS
treated for termites with perform guard, R-value 3.85 per
inch plus 8" concrete and ¼" air space and ½" gypsum
board waterproofed with Platon for a total U value of .06
or R-17 (there is a capillary break between the foundation
wall and the footing)
Roofs are of truss construction and insulated with 2.5” of
icynene air tight spray-on insulation around perimeter and
10.5 inches (30.45cm) blow-in 85% recycled cellulose for
a total U value of .02 or R-50.
Rim joists have 5" of icynene air tight spray-on insulation
everywhere plus 3.5" of fiber-glass in unfinished areas for
fire protection.
Windows are thermo-pane (2 panes), low-E, argon filled.
U value ranges from .29 to .35, SHGC is .31 to .34 All
windows were then sealed between the window and
sill/jambs/head from the inside with 2.5" of icynene air
tight spray-on insulation, R-3.85 per inch.
Savings in material usage was created from the use of
engineered wood. We used OSB sheathed SIPS, OSB,
fifty year warranted flooring, engineered floor joists, finger
jointed studs, parallam beams and engineered roof
trusses. the deck is a composite material made of
recycled plastic and wood fiber and all of the carpet is
PET recycled carpet.
120
97.8
100
80
1993 MEC
60
43.7
As Designed
40
22.1 22
20
7.4 5.1
0
Heat
Technical systems
Ventilation system, energy saving appliances, controls,
energy supply system, solar energy utilization.
HVAC system is for 3608 sq. ft. of conditioned space on
three floors, a heating load of 33,000 BTUs and a cooling
load of 27,000 BTUs.
The heat source is a 66,000 BTU, 65 gallon gas fired
sealed combustion, boiler rated, hot water heater with an
82 AFUE. This unit provides all domestic hot water and is
also connected by pump to a coil heat exchanger in the
air handler. Should it be desired this system could be
attached directly to solar thermal panel. The fireplace
(when used) is utilized for auxiliary heating.
Air ducts are installed in conditioned space. They are
sealed with painted on water-based sealant.
The cooling units are typically 18 SEER 1 ½ - 3 ton
variable speed electric air conditioner. The fresh air is
supplied by a energy recovery ventilator that operates
continuously and is ducted from the kitchen, baths and
laundry. The air handler has a variable speed fan which
runs continuously supplying from 700 cfm to 1500 cfm.
As the return air enters the air handler it passes an
ultraviolet air treatment system and enters an electronic
air filter which removes particles down to .3 microns, This
system is expected to have purified the air to 99.75%
germ/mold/bacteria free and filtered out all particles down
to .3 microns.
Cool
Water
Energy performance
Energy performance for the Ward Road house is based
on the 1993 Model Energy Code, Section 402 that is
typically better than the average home and is shown
above. This is a one-of-a-kind custom “site” designed
home built to accommodate the view. Solar orientation
was not feasible. Other models show energy results of
50% less usage because of proper orientations.
Annual energy consumption (MMBtu) and was verified as
5 Stars + with an energy rating point of 91.1
Total energy demand/yr kWh/m-sq. = 78.64
Heating and ventilation used/yr kWh/m-sq. = 46.45
Natural gas and electricity
Domestic hot water used/yr kWh/m-sq. = 17.14
Natural gas
Fans and pumps-in above numbers
Lights and appliances used/yr kWh/m-sq. = 15.04
This is from HERS calculations with defaults for
appliances.
Costs
The construction costs for the Ward Road Home (not
including land and sales fees are $107 per sq ft or
$1151/ m2. These homes are upscale homes with added
costs for trim and décor’.
Planning Tools
REM DESIGN was used to develop our building envelope
and REM RATE calculations were performed on six
different plans before construction.
Air Ducts were tested tight with an air blaster and stage
smoke and visible leaks were sealed during the test.
Market communications (MC) strategy
NeXus Environmental Consulting was retained in
late 2003 to market the existing speculative homes as
well as attract buyers for additional building throughout
the greater Kansas City Region.
A Core Value Mosaic was developed along with
consumer Benefit Ladders and SWOT analysis. Key
demographic and psychographics sectors were
identified. Most notably the growing influence of the
emerging Cultural Creative (CC) consumer segment 1
was considered.
Logo design is deemed extremely important to the
Cultural Creative. Symbols are used to help brand the
technical benefits of sustainable housing. Brand apostles
among diverse CC companies have been recruited.
Current price points and floor plans were decided upon
before NeXus was retained. There is a stronger demand
toward the median price in the area. This is driven by
demographics, but value based decisions are the primary
reason customer contacts have been made for new
construction.
Competitive benefits and pinpointing branding
opportunities has been the thrust of this campaign. An
Integrated Market Communication strategy that
uncovers these consumers is the focus of the execution
strategy. It is primarily a relationship driven strategy.
As of this writing, trade presentations are planned. Cost
sharing for publications will be among companies who
supply materials as well as the builder and a local
remodeled. After sale follow up consists of a newsletter
periodically sent to homeowners.
The Execution Strategy:
Highly selective advertising aimed toward the local
publications that the LOHAS 1, 2 consumer may read
have been targeted. Advertisements have
accompanied articles targeted to specific readership
profiles. Advertisement in mainstream (Real Estate)
publications are producing poor results.
References and Further Information
Direct marketing has been limited (due to unavailability
of appropriate list s for this segment), however,
medical doctors, doctors of chiropractic as well as other
“holistic” health care practitioners have been targeted
for direct mail. Health clubs, gardening organizations
and other selected affiliations are also being targeted.
1.
2.
A Compendium of Surveys in the US, Guy Holt, November 2002
Update April 2004
The Natural Marketing Institute, Understanding the LOHAS
Consumer Group: A Focus on Green Building
Project Team: David Roberts and Rich Hillman, Envision
Development Corporation, www.envisionhomes.com
Project Coordinator: Rich Hillman
Marketing and Communication, NeXus Environmental
Consulting, Guy Holt, [email protected]
Future Construction using these systems will be
developed by Vision Homes.
Common text about Task 28
Public relations programs include a series of articles
in local publications along with local and national
press release. Recent contacts from nationally
syndicated TV shows and local newspapers have been
forthcoming. The articles feature a small footer with
contact points and web addresses have been
successful.
www.iea.shc.org
www.ecbs.org